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FINAL
EXPERT COMMITTEE ON BIOLOGICAL STANDARDIZATION
Geneva, 19 to 23 October 2009
GUIDELINES ON EVALUATION OF SIMILAR
BIOTHERAPEUTIC PRODUCTS (SBPs)
© World Health Organization 2009
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Adopted by the 60th meeting of the WHO Expert Committee on Biological Standardization, 19-23 October 2009. A
definitive version of this document, which will differ from this version in editorial but not scientific details, will be
published in the WHO Technical Report Series.
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Table of contents
1. 3
2. 4
3. 4
4. 5
5. Scientific considerations and concept for 7
6. Key principles for the licensing 8
7. Reference 9
8. 10
9. .16
10. 19
11. 28
12. Prescribing information 29
13. Roles and responsibilities .29
Authors 31
33
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1 Introduction
Biotherapeutic products (biotherapeutics) have a successful record in treating many life-threatening and chronic diseases. However, their cost has often been high, thereby limiting their
access to patients, particularly in developing countries. Recently, the expiration of patents and/or
data protection for the first major group of originator’s biotherapeutics has ushered in an era of
products that are designed to be ‘similar’ to a licensed originator product. These products rely, in
part, for their licensing on prior information regarding safety and efficacy obtained with the
originator products. The clinical experience and established safety profile of the originator
products should contribute to the development of similar biotherapeutic products (SBPs). A
variety of terms, such as 'biosimilar products', 'follow-on protein products' and 'subsequent-entry
biologics' have been coined by different jurisdictions to describe these products.
The term 'generic' medicine is used to describe chemical, small molecule medicinal products that
are structurally and therapeutically equivalent to an originator product whose patent and/or data
protection period has expired. The demonstration of bioequivalence of the generic medicine with
a reference product is usually appropriate and sufficient to infer therapeutic equivalence between
the generic medicine and the reference product. However, the approach established for generic
medicines is not suitable for development, evaluation and licensing of SBPs since
biotherapeutics consist of relatively large, and complex proteins that are difficult to characterize.
The clinical performance of biotherapeutics can also be much influenced by the manufacturing
process and some clinical studies will also be required to support the safety and efficacy of a
SBP.
As part of its mandate for assuring global quality, safety and efficacy of biotherapeutics, the
World Health Organization (WHO) provides globally accepted norms and standards for the
evaluation of these products 1, 2. Written standards established through the Expert Committee on
Biological Standardization (ECBS) serve as a basis for setting national requirements for
production, quality control and overall regulation of biological medicines. In addition,
International Standards for measurement are essential tools for the establishment of potency for
biological medicines worldwide 3. Often they are used as primary standards for calibration of the
secondary standards that are directly used in the biological assays.
An increasingly wide range of ‘SBPs1’ are under development or are already licensed in many
countries and a need for guidelines for their evaluation and overall regulation was formally
recognized by the WHO in 2007 4. This document is intended to provide guidance for the
development and evaluation of such biotherapeutics. However, the guidelines will serve as a
living document that will be developed further in the line with the progress in scientific
knowledge and experience.
It is essential that the standard of evidence supporting the decisions to license SBPs be sufficient
to ensure that the product meets acceptable levels of quality, safety and efficacy to ensure public
health. Also, it is expected that the elaboration of the data requirements and considerations for
1
Not all products deemed to be ‘SBPs’ will be consistent with the definition and/or process for evaluation of SBPs
as described in this guideline
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the licensing of these products will facilitate development of and worldwide access to
biotherapeutics of assured quality, safety and efficacy at more affordable prices. In most cases,
their authorization will be evaluated on a case-by-case basis, and the amount of data required by
a National Regulatory Authority (NRA) may vary. However, it is expected that a guideline on
the scientific principles for evaluation of SBPs will help harmonize the requirements worldwide
and will lead to greater ease and speed of approval and assurance of the quality, safety and
efficacy of these products. It is important to note that biotherapeutics which are not shown to be
similar to a RBP as indicated in this guideline should not be described as 'similar', nor called a
'SBP'. Such products could be licensed through the usually processes using a more extensive
non-clinical and clinical data set or full licensing application.
It was recognized that a number of important issues associated with the use of SBPs need to be
defined by the national authorities. They include but are not limited to the following:
•
•
•
intellectual property issues;
interchangeability and substitution of SBP with RBP; and
labelling and prescribing information.
Therefore, the above mentioned issues are not elaborated in this document.
2 Aim
The intention of this document is to provide globally acceptable principles for licensing
biotherapeutic products that are claimed to be similar to biotherapeutic products of assured
quality, safety, and efficacy that have been licensed based on a full licensing dossier. On the
basis of proven similarity, the licensing of a SBP will rely, in part, on non-clinical and clinical
data generated with an already licensed reference biotherapeutic product (RBP). This guideline
can be adopted as a whole, or partially, by NRAs worldwide or used as a basis for establishing
national regulatory frameworks for licensure of these products.
3 Scope
This guideline applies to well-established and well-characterized biotherapeutic products such as
recombinant DNA-derived therapeutic proteins.
Vaccines, plasma derived products, and their recombinant analogues are excluded from the scope
of this document. WHO recommendations and regulatory guidance for these products are
available elsewhere (/biologicals/areas/en/).
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4 Glossary
The definitions given below apply to the terms used in this guideline. They may have different
meanings in other contexts.
Comparability exercise
Head-to-head comparison of a biotherapeutic product with a licensed originator product with the
goal to establish similarity in quality, safety, and efficacy. Products should be compared in the
same study using the same procedures.
Drug product
A pharmaceutical product type that contains a drug substance, generally in association with
excipients.
Drug substance
The active pharmaceutical ingredient and associated molecules that may be subsequently
formulated, with excipients, to produce the drug product. It may be composed of the desired
product, product-related substances, and product- and process-related impurities. It may also
contain other components such as buffers.
Equivalent
Equal or virtually identical in the parameter of interest. Equivalent efficacy of two medicinal
products means they have similar (no better and no worse) efficacy and any observed differences
are of no clinical relevance.
Generic medicine
A generic medicine contains the same active pharmaceutical ingredient as and is bioequivalent to
an originator (comparator) medicine. Since generic medicines are identical in the active
pharmaceutical substance, dose, strength, route of administration, safety, efficacy, and intended
use, they can be substituted for the originator product.
Head-to-head comparison
Direct comparison of the properties of the SBP with the RBP in the same study.
Immunogenicity
The ability of a substance to trigger an immune response or reaction (e.g. development of
specific antibodies, T cell response, allergic or anaphylactic reaction).
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Impurity
Any component present in the drug substance or drug product that is not the desired product, a
product-related substance, or excipient including buffer components. It may be either process- or
product-related.
Non-inferior
Not clinically inferior to a comparator in the parameter studied. A non-inferiority clinical trial is
one which has the primary objective of showing that the response to the investigational product
is not clinically inferior to a comparator by a pre-specified margin.
Originator product
A medicine which has been licensed by the national regulatory authorities on the basis of a full
registration dossier; i.e. the approved indication(s) for use were granted on the basis of full
quality, efficacy and safety data.
Pharmacovigilance
The science and activities relating to the detection, assessment, understanding and prevention of
adverse effects or any other drug related problems.
Reference biotherapeutic product (RBP)
A reference biotherapeutic product is used as the comparator for head-to-head comparability
studies with the similar biotherapeutic product in order to show similarity in terms of quality,
safety and efficacy. Only an originator product that was licensed on the basis of a full
registration dossier can serve as a RBP. It does not refer to measurement standards such as
international, pharmacopoeial, or national standards or reference standards.
Similarity
Absence of a relevant difference in the parameter of interest.
Similar biotherapeutic product (SBP)
A biotherapeutic product which is similar in terms of quality, safety and efficacy to an already
licensed reference biotherapeutic product.
Well-established biotherapeutic product
Well-established biotherapeutic product is the one that has been marketed for a suitable period of
time with a proven quality, efficacy and safety.
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5 Scientific considerations and concept for licensing SBPs
For the licensing of generic medicines, the regulatory framework is well-established in most
countries. Demonstration of structural sameness and bioequivalence of the generic medicine with
the reference product is usually appropriate to infer (conclude) therapeutic equivalence between
the generic and the reference product. However, the generic approach is not suitable for the
licensing of SBPs since biotherapeutic products usually consist of relatively large and complex
entities that are difficult to characterize. In addition, SBPs are manufactured and controlled
according to their own development since the manufacturer of a SBP normally does not have
access to all the necessary manufacturing information on the originator product. However, even
minor differences in the manufacturing process may affect the pharmacokinetics,
pharmacodynamics, efficacy and/or safety of biotherapeutic products. As a result, it has been
agreed that the normal method for licensing generic medicines through bioequivalence studies
alone is not scientifically appropriate for SBPs.
Decision making regarding the licensing of SBPs should be based on scientific evidence. The
onus is on a manufacturer of a SBP to provide the necessary evidence to support all aspects of an
application for licensing. As with any drug development program, the development of a SBP
involves a stepwise approach starting with characterization and evaluation of quality attributes of
the product and followed by non-clinical and clinical studies. Comprehensive characterization
and comparison at the quality level are the basis for possible data reduction in the non-clinical
and clinical development. If differences between the SBP and the RBP are found at any step, the
underlying reasons for the differences should be investigated. Differences should always be
explained and justified and may lead to the requirement of additional data (e.g. safety data).
In addition to the quality data, SBPs require non-clinical and clinical data generated with the
product itself. The amount of non-clinical and clinical data considered necessary will depend on
the product or class of products, the extent of characterization possible undertaken using state-of-the-art analytical methods, on observed or potential differences between the SBP and the RBP,
and on the clinical experience with the product class (e.g. safety/immunogenicity concerns in a
specific indication). A case by case approach is clearly needed for each class of products.
A SBP is intended to be similar to a licensed biotherapeutic product for which there is a
substantial evidence of safety and efficacy. The ability for the SBP to be authorized based on
reduced non-clinical and clinical data depends on proof of its similarity to an appropriate RBP
through the comparability exercise. Manufacturers should demonstrate a full understanding of
their product, consistent and robust manufacture of their product, and submit a full quality
dossier that includes a complete characterization of the product. The comparability exercise
between the SBP and the RBP in the quality part represents an additional element to the
‘traditional’ full quality dossier. The reduction in data requirements is therefore only possible for
the non-clinical and/or clinical parts of the development program. The dosage form and route of
administration of the SBP should be the same as for the RBP.
Studies must be comparative in nature employing analytical strategies (methods) that are
sensitive to detect potential differences between the SBP and the RBP. The main clinical studies
should use the final formulation derived from the final process material of the SBP. Otherwise,
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additional evidence of comparability will be required to demonstrate that the SBP to be marketed
is comparable to that used in the main clinical studies.
If similarity between the SBP and the RBP has been convincingly demonstrated, the SBP may be
approved for use in other clinical indications of the RBP that have not directly been tested in
clinical trials if appropriate scientific justification for such extrapolation is provided by the
manufacturer (see section 10.7). Significant differences between the SBP and the chosen RBP
detected during the comparability exercise would be an indication that the products are not
similar and more extensive non-clinical and clinical data may be required to support the
application for licensing.
Comparability exercise
The comparability exercise for a SBP is designed to show that the SBP has highly similar quality
attributes when compared to the RBP. However, it also includes the non-clinical and clinical
studies to provide an integrated set of comparative data. The comparability data at the level of
quality can be considered to be an additional set of data over that which is normally required for
an originator product developed as a new and independent product. This is the basis for reducing
the non-clinical and clinical data requirements.
Although the quality comparisons are undertaken at various points throughout the quality
application/dossier, a distinction should be made between usual quality data requirements and
those presented as part of the comparability exercises. It may be useful to present these as a
separate section in the quality module.
6 Key principles for the licensing of SBPs
a. The development of a SBP involves stepwise comparability exercise(s) starting with
comparison of the quality characteristics of the SBP and RBP. Demonstration of
similarity of a SBP to a RBP in terms of quality is a prerequisite for the reduction of the
non-clinical and clinical data set required for licensure. After each step of the
comparability exercise, the decision to proceed further with the development of the SBP
should be evaluated.
b. The basis for licensing a product as a SBP depends on its demonstrated similarity to a
suitable RBP in quality, non-clinical, and clinical parameters. The decision to license a
product as a SBP should be based on evaluation of the whole data package for each of
these parameters.
c. If relevant differences are found in the quality, non-clinical, or clinical studies, the
product will not likely qualify as a SBP and a more extensive non-clinical and clinical
data set will likely be required to support its application for licensure. Such a products
should not qualify as a SBP as defined in this guideline.
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d. If comparability exercises and/or studies with the RBP are not performed throughout the
development process as outlined in this guidance document, the final product should not
be referred to as a SBP.
e. SBPs are not “generic medicines” and many characteristics associated with the
authorization process generally do not apply.
f. SBPs, like other biotherapeutic products, require effective regulatory oversight for the
management of their potential risks and in order to maximize their benefits.
7 Reference biotherapeutic product
Comprehensive information on the RBP provides the basis for establishing the safety, quality,
and effectiveness profile to which the SBP is compared. The RBP also provides the basis for
dose selection and route of administration, and is utilized in the comparability studies required to
support the licensing application. The demonstration of an acceptable level of similarity between
the SBP and RBP provides the rationale for utilizing a reduced non-clinical and clinical data set
to support the application for market authorization of the SBP. Hence the RBP is central to the
licensing of a SBP.
To support licensure of the SBP, similarity of the SBP to the RBP should be demonstrated
through head-to-head comparisons with the RBP. The same RBP should be used throughout the
entire comparability exercise.
The choice of a RBP is of critical importance for the evaluation of SBP. The rationale for the
choice of the RBP should be provided by the manufacturer of the SBP in the submission to the
NRA. Traditionally, NRAs have required the use of a nationally licensed reference product for
licensing of generic medicines. This practice may not be feasible for countries lacking
nationally-licensed RBPs. NRAs may need to consider establishing additional criteria to guide
the acceptability of using a RBP licensed or resourced in other countries. The use of reference
products with proven efficacy and safety in a given population will be one of the factors to
consider. Another parameter may be market experience in addition to the duration and marketed
use.
Considerations for choice of reference biotherapeutic product
Since the choice of a RBP is essential to the development of a SBP, the following should be
considered.
• The RBP should have been marketed for a suitable duration and have a volume of
marketed use such that the demonstration of similarity to it brings into relevance a
substantial body of acceptable data regarding the safety and efficacy.
• The manufacturer needs to demonstrate that the chosen RBP is suitable to support the
application for marketing authorization of a SBP.
• The RBP should be licensed based on a full quality, safety, and efficacy data. Therefore a
SBP should not be considered as a choice for RBP.
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• The same RBP should be used throughout the development of the SBP (i.e. for the
comparative quality, non-clinical, and clinical studies).
• The drug substance of the RBP and the SBP must be shown to be similar.
• The dosage form and route of administration of the SBP should be the same as that of the
RBP.
• The following factors should be considered in the choice of a RBP that is marketed in
another jurisdiction.
o The RBP should be licensed and widely marketed in another jurisdiction which
has well-established regulatory framework and principles, as well as considerable
experience of evaluation of biotherapeutic products, and post-marketing
surveillance activities.
o The acceptance of a RBP for evaluation of a SBP in a country does not imply
approval for use of the RBP by the NRA of that country.
8 Quality
The quality comparison showing molecular similarity between the SBP and the RBP is
indispensable to provide rationale for predicting that the clinical safety and efficacy profile of the
RBP should also apply to the SBP so that the extent of the non-clinical and clinical data required
with the SBP can be reduced. Ideally, development of a SBP involves thorough characterization
of a number of representative lots of the RBP and then engineering a manufacturing process that
will reproduce a product that is highly similar to the RBP in all clinically relevant product quality
attributes; i.e. those product attributes that may impact clinical performance. A SBP is generally
derived from a separate and independent master cell bank using independent manufacturing
processes and control. These should be selected and designed to meet the required comparability
criteria. A full quality dossier for both drug substance and drug product is always required,
which complies with the standards as required by NRAs for originator products.
Increased knowledge of the relationship between biochemical, physicochemical, and biological
properties of the product and clinical outcomes will facilitate development of a SBP. Due to the
heterogeneous nature of proteins (especially those with extensive post-translational
modifications such as glycoproteins), the limitations of some analytical techniques, and the
generally unpredictable nature of the clinical consequences of minor differences in protein
structural/ physico-chemical properties, the evaluation of comparability will have to be carried
out independently for each product. For example, oxidation of certain methionine residues in one
protein may have no impact on clinical activity whereas in another protein it may significantly
decrease the intrinsic biological activity of the protein, or may increase its immunogenicity.
Thus, differences in the levels of Met oxidation in the RBP and SBP would need to be evaluated
and, if present, their clinical relevance would be evaluated and discussed.
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To evaluate comparability, the manufacturer should carry out a comprehensive physicochemical
and biological characterization of the SBP in head-to-head comparisons with the RBP. All
aspects of product quality and heterogeneity should be assessed (see characterization below).
A high degree of similarity between the SBP and the RBP is the basis for reducing non-clinical
and clinical requirements for licensing. However, some differences are likely to be found, e.g.
due to differences in impurities or excipients. Such differences should be assessed for their
potential impact on clinical safety and efficacy of the SBP and a justification, e.g. own study
results or literature data, for allowing such differences provided. Differences of unknown clinical
relevance, particularly regarding safety, may have to be addressed in additional studies pre- or
post-marketing. Differences in quality attributes known to have potential impact on clinical
activity will influence the judgment of consideration whether to name such product as 'SBP'. For
example, if differences are found in glycosylation patterns that alter the biodistribution of the
product and thereby change the dosing scheme, then this product can not be considered a SBP.
Other differences between the SBP and RBP may be acceptable, and would not trigger the need
for extra non-clinical and/or clinical evaluation. For example, a therapeutic protein that has lower
levels of protein aggregates would, in most cases, be predicted to have a better safety profile than
the RBP and would not need added clinical evaluation. Along the same lines, if heterogeneity in
the terminal amino acids of the RBP is known, and sufficiently documented, without affecting
the bioactivity, distribution, or immunogenicity of the RBP or similar products in its class, then
there may be no need for added clinical safety or efficacy studies based upon this heterogeneity
of the RPB and SBP.
Due to the unavailability of drug substance for the RBP, the SBP manufacturer will usually be
using commercial drug product for the comparability exercise. The commercial drug product will,
by definition, be in the final dosage form containing the drug substance(s) formulated with
excipients. It should be verified that these do not interfere with analytical methods and thereby
impact the test results. If the drug substance in the RBP needs to be purified from a formulated
reference drug product in order to be suitable for characterization, studies must be carried out to
demonstrate that product heterogeneity and relevant attributes of the active moiety are not
affected by the isolation process. The approach employed to isolate and compare the SBP to the
RBP should be justified and demonstrated, with data, to be appropriate for the intended purpose.
Where possible, the product should be tested with and without manipulation.
8.1 Manufacturing process
Manufacture of a SBP should be based on a comprehensively designed production process taking
all relevant guidelines into account. The manufacturer needs to demonstrate the consistency and
robustness of the manufacturing process by implementing Good Manufacturing Practices 5,
modern quality control and assurance procedures, in-process controls, and process validation.
The manufacturing process should meet the same standards as required by the NRA for
originator products. The manufacturing process should be optimized to minimize differences
between the SBP and RBP in order to (a) maximize the ability to reduce the clinical testing
requirements for the SBP based upon the clinical history of the RBP, and (b) minimize any
predictable impact on the clinical safety and efficacy of the product. Some differences between
the SBP and RBP are expected and may be acceptable, provided, appropriate justification with
regard to lack of impact on clinical performance is given.
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It is understood that a manufacturer developing a SBP does not have access to confidential
details of the manufacturing process of the RBP such that the process will differ from the
licensed process for the RBP (unless there is a contractual arrangement with the manufacturer of
the RBP). The manufacturing process for a SBP should employ state-of-the-art science and
technology to achieve a high quality SBP that is as similar as possible to the RBP. This will
involve evaluating the RBP extensively prior to developing the manufacturing process for the
SBP. The SBP manufacturer should assemble all available knowledge of the RBP concerning the
type of host cell, formulation and container closure system used for marketing the RBP. If
applicable, the SBP manufacturer should then determine the potential impact of changing any
one of these elements on product quality, safety and efficacy based on available evidence from
public information, experience with previous use of the RBP. SBP manufacturer is encouraged to
apply this knowledge to the design of the manufacturing process. The rationale for accepting
these differences needs to be justified based upon sound science and clinical experience, either
with the SBP, or the RBP.
As a general rule, the product should be expressed and produced in the same host cell type as the
RBP (e.g. , CHO cells, etc.) in order to minimize the potential for important changes to
critical quality attributes of the protein and to avoid introduction of certain types of process-related impurities (e.g. host cell proteins, endotoxins, yeast mannans) that could impact clinical
outcomes and immunogenicity. The host cell type for manufacture of the SBP should only be
changed if the manufacturer can demonstrate convincingly that the structure of the molecule is
not affected or that the clinical profile of the product will not change. For example, somatropin
produced in yeast cells appears to have similar characteristics to somatropin expressed in E. coli.
In most cases, however, the use of a different host cell type will not be feasible for glycoproteins
because glycosylation patterns vary significantly between different host cell types.
A complete description and data package should be provided that delineates the manufacturing
process, starting with development of expression vectors and cell banks, cell culture/
fermentation, harvest, purification and modification reactions, filling into bulk or final containers,
and storage. The development studies conducted to establish and validate the dosage form,
formulation, and container closure system (including integrity to prevent microbial
contamination) and usage instructions should be also documented (see relevant guidelines such
as ICH).
8.2 Characterization
Thorough characterization of both RBP and SBP should be carried out using appropriate, state-of-the-art biochemical, biophysical, and biological analytical techniques. For the active
ingredient(s) (i.e. the desired product), details should be provided on primary and higher-order
structure, post-translational modifications (including but not limited to glycoforms), biological
activity, purity, impurities, product-related (active) substances (variants), and immunochemical
properties, where relevant.
When conducting a comparability exercise, head-to-head characterization studies are required to
compare the SBP and the RBP. The primary structure of SBP and the RBP should be identical.
If differences between the SBP and the RBP are found, their potential impact on safety and
efficacy of the SBP should be evaluated. The predefined limits need to be considered in advance.
The assessment of the results should include the investigation of the differences found between
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SBP and RBP. This determination will be based upon knowledge of the relationship between
product quality attributes and clinical activity of the RBP and related products, the clinical
history of the RBP, and lot-to-lot differences for commercial lots of the RBP. For example,
quality attributes such as composition and profile of glycosylation, biological activity which is
known to be related to clinical activity, and receptor binding activity should be justified.
Knowledge of the analytical limitations of each technique used to characterize the product (e.g.
limits of sensitivity, resolving power) should be applied when making a determination of
similarity. Representative raw data should be provided for all complex analytical methods (e.g.
high quality reproductions of gels, chromatograms, etc.) in addition to tabular data summarizing
the complete data set and showing the results of all release and characterization analyses carried
out on the SBP and the RBP.
The following criteria should be considered when conducting the comparability exercise:
8.2.1 Physicochemical Properties
The physicochemical characterization should include the determination of primary and higher
order structure (secondary/tertiary/quaternary) using appropriate analytical methods (e.g. mass
spectrometry, NMR) and other biophysical properties. An inherent degree of structural
heterogeneity occurs in proteins due to the biosynthesis process such that the RBP and the SBP
are likely to contain a mixture of post-translationally modified forms. Appropriate efforts should
be made to investigate, identify and quantify these forms.
8.2.2 Biological Activity
Biological activity is the specific ability or capacity of the product to achieve a defined
biological effect. It serves multiple purposes in the assessment of product quality and is required
for characterization, and batch analysis. Ideally, the biological assay will reflect the understood
mechanism of action of the protein and will thus serve as a link to clinical activity. A biological
assay is a quality measure of the ‘function’ of the protein product and can be used to determine
whether a product variant has the appropriate level of activity (i.e. a product-related substance)
or is inactive (and is therefore defined as an impurity). The biological assay also complements
the physicochemical analyses by confirming the correct higher order structure of the molecule.
Thus, the use of a relevant biological assay(s) with appropriate precision and accuracy provides
an important means of confirming that a significant functional difference does not exist between
the SBP and the RBP.
For a product with multiple biological activities, manufacturers should perform, as part of
product characterization, a set of relevant functional assays designed to evaluate the range of
activities of the product. For example, certain proteins possess multiple functional domains that
express enzymatic and receptor-binding activities. In such situations, manufacturers should
evaluate and compare all relevant functional activities of the SBP and RBP.
Potency is the quantitative measure of the biological activity. A relevant, validated potency assay
should be part of the specification for drug substance and/or drug product. The results of the
potency assay should be provided and expressed in units of activity. Where possible (e.g. for in
vitro biochemical assays such as enzyme assays or binding assays), the results may be expressed
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as specific activities (e.g. units/mg protein). Assays should be calibrated against an international
or national standard or reference reagent, when available and appropriate. WHO provides
international standards and reference reagents, which serve as reference sources of defined
biological activity expressed in an international unit or Unit. International standards and
reference reagents are intended for calibration of national reference standards.
(/biologicals/reference_preparations/en/). Therefore, international or national
standards and reference reagents should be used to determine the potency and to express results
in IU or U. They are not intended for use as a RBP during the comparability exercise.
Biological assays can be used for other purposes than determination of potency. For example, a
relevant biological assay is essential for determining whether antibodies that develop in response
to the product have neutralizing activity that impacts the biological activity of the product and/or
endogenous counterparts, if present (see section 10.6).
8.2.3 Immunochemical Properties
When immunochemical properties are part of the characterization (e.g. for antibodies or
antibody-based products), the manufacturer should confirm that the SBP is comparable to the
RBP in terms of specificity, affinity, binding kinetics, and Fc functional activity, where relevant.
8.2.4 Impurities
Due to the limited access to all necessary information on the manufacturing process as well as
the drug substance of the originator product, it is recognized that the evaluation of similarity of
the impurity profiles between SBP and RBP will be generally difficult. Nevertheless, process-
and product-related impurities should be identified, quantified by state-of-the-art technology and
compared between the SBP and RBP. Some differences may be expected because the proteins
are produced by different manufacturing processes. If significant differences are observed in the
impurity profile between the SBP and the RBP, their potential impact on efficacy and safety,
including immunogenicity, should be evaluated. It is critical to have suitable assays for process-related impurities, specific to the cell line used for production.
8.3 Specifications
Specifications are employed to verify the routine quality of the drug substance and drug product
rather than to fully characterize them. As for any biotherapeutic product, specifications for a SBP
should be set as described in established guidelines and monographs, where these exist. It should
be noted that pharmacopoeial monographs may only provide a minimum set of requirements for
a particular product and additional test parameters may be required. Reference to analytical
methods used and acceptance limits for each test parameter of the SBP should be provided and
justified. All analytical methods referenced in the specification should be validated; the
corresponding validation should be documented.
Specifications for a SBP will not be the same as for the RBP since the manufacturing processes
will be different and different analytical procedures and laboratories will be used for the assays.
Nonetheless, the specifications should capture and control important product quality attributes
known for the RBP (e.g. correct identity; purity, potency; molecular heterogeneity in terms of
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size, charge, and hydrophobicity, if relevant; degree of sialylation; number of individual
polypeptide chains; glycosylation of a functional domain; aggregate levels; impurities such as
host cell protein and DNA). The setting of specifications should be based upon the
manufacturer’s experience with the SBP (e.g. manufacturing history; assay capability; safety and
efficacy profile of the product) and the experimental results obtained by testing and comparing
the SBP and RBP. Sufficient lots of SBP should be employed in setting specifications. The
manufacturer should demonstrate, whenever possible, that the limits set for a given specification
are not significantly wider than the range of variability of the RBP over the shelf-life of the
product, unless justified.
8.4 Analytical techniques
Although the power of analytical methods for characterization of proteins has increased
dramatically over the past few decades, there are still obstacles to completely characterizing
complex biotherapeutic products. A battery of state-of-the-art analyses is needed to determine
structure, function, purity, and heterogeneity of the products. The methods employed should
separate and analyze different variants of the product based upon different underlying chemical,
physical, and biological properties of protein molecules. For example, PAGE, ion exchange
chromatography, isoelectric focusing, and capillary electrophoresis all separate proteins based
upon charge, but they do so under different conditions and based upon different physicochemical
properties. As a result, one method may detect variants that another method does not detect. The
goal of the comparability investigation is to be as comprehensive as possible in order to
minimize the possibility of undetected differences between the RBP and SBP that may impact
clinical activity. The analytical limitations of each technique (e.g. limits of sensitivity, resolving
power) should be considered when making a determination of similarity between a SBP and a
RBP.
The measurement of quality attributes in characterization studies (versus in the specifications)
does not necessarily require the use of validated assays, but the assays should be scientifically
sound and qualified; i.e. they should provide results that are meaningful and reliable. The
methods used to measure quality attributes for lot release should be validated in accordance with
relevant guidelines, as appropriate. A complete description of the analytical techniques employed
for release and characterization of the product should be provided in the license application.
8.5 Stability
The stability studies should be in compliance with relevant guidance as recommended by the
NRA. Studies should be carried out to show which release and characterization methods are
stability-indicating for the product. Generally, stability studies should be summarized in an
appropriate format such as tables, and they should include results from accelerated degradation
studies and studies under various stress conditions (e.g. temperature, light, humidity, mechanical
agitation). Accelerated stability studies comprise an important element of the determination of
similarity between a SBP and a RBP because they can reveal otherwise-hidden properties of a
product that warrant additional evaluation. They are also important for identifying the
degradation pathways of a protein product. The results obtained from accelerated stability studies
may show that additional controls should be employed in the manufacturing process and during
shipping and storage of the product in order to ensure the integrity of the product. Head-to-head
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accelerated stability studies comparing the SBP to the RBP will be of value in determining the
similarity of the products by showing a comparable degradation profile. However, currently,
stress testing carried out in a comparative manner does not provide an added value.
Representative raw data showing the degradation profiles for the product should be provided in
the license application. The stability data should support the conclusions regarding the
recommended storage and shipping conditions and the shelf life/storage period for the drug
substance, drug product, and process intermediates that may be stored for significant periods of
time. Stability studies on drug substance should be carried out using containers and conditions
that are representative of the actual storage containers and conditions. Stability studies on drug
product should be carried out in the intended drug product container-closure system. Real
time/real temperature stability studies will determine the licensed storage conditions and
expiration dating for the product. This may or may not be the same as for the RBP.
9 Non-clinical evaluation
The non-clinical part of the guideline addresses the pharmaco-toxicological assessment of the
SBP. The establishment of safety and efficacy of a SBP usually requires the generation of some
non-clinical data with the SBP.
9.1 General considerations
The demonstration of a high degree of molecular similarity between the SBP and RBP should
significantly reduce the need for non-clinical studies since the RBP will already have a
significant clinical history. Non-clinical studies, should be conducted with the final formulation
of the SBP intended for clinical use, unless otherwise justified.
The design of an appropriate non-clinical study program requires a clear understanding of the
product characteristics. Results from the physico-chemical and biological characterization
studies should be reviewed from the point-of-view of potential impact on efficacy and safety.
When developing a SBP some existing guidelines may be relevant and should therefore be taken
into account; e.g. the ´Note for preclinical safety evaluation of biotechnology-derived
pharmaceuticals` (ICH S6) 6.
SBPs often require the application of unique approaches to assessing their safety in non-clinical
studies. Problems in the non-clinical evaluation of SBPs containing biotechnology-derived
recombinant proteins as drug substance are often related to the fact that these products:
- may show species-specific pharmacodynamic activity such that it is sometimes difficult to
identify a relevant species for pharmacodynamic and toxicological evaluation; and/or
- will, as ´foreign proteins`, usually elicit an antibody response in long-term animal studies. Thus,
the results of subchronic or chronic repeat dose studies may be difficult to interpret due to the
formation of antibody complexes with the drug substance.
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9.2 Special considerations
Non-clinical evaluation of a new biotherapeutic normally encompasses a broad spectrum of
pharmacodynamic, pharmacokinetic and toxicological studies 6. The amount of additional non-clinical data required to establish safety and efficacy of a SBP is considered to be highly
dependent on the product and on substance-class related factors. Factors that often elicit the need
for additional non-clinical studies include, but are not restricted to:
- Quality-related factors:
• Significant differences in the cell expression system compared with the RBP
• Significant differences in purification methods used
• The presence of a complex mixture of less well characterized product- and/or process-related impurities
- Factors related to pharmaco-toxicological properties of the drug substance:
• Mechanism(s) of drug action are unknown or poorly understood
• The drug substance is associated with significant toxicity and/or has a narrow therapeutic
index
• Limited clinical experience with the RBP
Depending on these factors, the spectrum of studies required to establish safety and efficacy of
the SBP may vary considerably and should be defined on a case-by-case basis. For example, in
the case of a highly complex drug substance that is difficult to characterize by analytical
techniques and which possesses a narrow therapeutic index, the non-clinical development
program may encompass a significant portion of the spectrum of studies described in relevant
guidelines such as ICH S6 6. On the other hand, for products for which the drug substance and the
impurity profile are well characterized by analytical means, which possess a wide therapeutic
index and for which an extensive clinical experience is available, the non-clinical development
program will likely be more limited. However, a head-to-head repeat dose toxicity study should
usually constitute a minimum requirement for non-clinical evaluation of a SBP. The non-clinical
studies constitute a part of the overall comparability exercise. Therefore, the studies should be
comparative in nature and designed to detect differences in response between the SBP and the
RBP and not just the response to the SBP alone. Any deviation to this approach should be
appropriately justified.
In vitro studies:
Assays like receptor-binding studies or cell-based assays (e.g. cell-proliferation or cytotoxicity
assays) should normally be undertaken in order to establish comparability of the biological/
pharmacodynamic activity of the SBP and RBP. Such data are usually already available from the
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biological assays described in the quality part of the dossier (see chapter 8.2.2). Reference to
these studies can be made in the non-clinical part of the dossier.
In vivo studies:
Animal studies should be designed to maximize the information obtained. Such studies should be
comparative in nature (see above), should be performed in (a) species known to be relevant (i.e.
a species in which the RBP has been shown to possess pharmacodynamic and/or toxicological
activity) and employ state-of-the-art technology. Where the model allows, consideration should
be given to monitoring a number of endpoints such as:
- Biological/ pharmacodynamic activity relevant to the clinical application. These data should
usually be available from biological assays described in the quality part of the dossier (see
chapter 8.2.2) and reference to these studies can be made in the non-clinical part of the dossier. If
feasible, biological activity may be evaluated as part of the non-clinical repeat dose toxicity
study (described below). In vivo evaluation of biological/ pharmacodynamic activity may be
dispensable if in vitro assays are available, which have been validated to reliably reflect the
clinically relevant pharmacodynamic activity of the RBP.
- Non-clinical toxicity as determined in at least one repeat dose toxicity study in a relevant
species and including toxicokinetic measurements. These measurements should include
determination and characterization of antibody responses, including anti-product antibody titres,
cross reactivity with homologous endogenous proteins, and product neutralizing capacity. The
duration of the studies should be sufficiently long to allow detection of potential differences in
toxicity and antibody responses between the SBP and RBP.
Besides being a part of the overall comparability exercise, the comparative repeat dose toxicity
study is considered to provide reassurance that no ´unexpected` toxicity will occur during
clinical use of the SBP. If performed with the final formulation intended for clinical use, the
repeat dose toxicity study will, in principle, allow for detection of potential toxicity associated
with both the drug substance and product- and process-related impurities.
Although the predictive value of animal models for immunogenicity in humans is considered low,
antibody measurements, if applicable, should be included in the repeat dose toxicity study to aid
in the interpretation of the toxicokinetic data and to help assess, as part of the overall
comparability exercise, whether important differences in structure or immunogenic impurities
exist between the SBP and RBP (the immunological response may be sensitive to differences not
detected by laboratory analytical procedures).
Depending on the route of administration, local tolerance may need to be evaluated. If feasible,
this evaluation may be performed as part of the described repeat dose toxicity study.
On the basis of the demonstration of similarity between the SBP and RBP by the additional
comparability exercise performed as part of the quality evaluation, normally other routine
toxicological studies such as safety pharmacology, reproductive toxicology, genotoxicity and
carcinogenicity studies are not generally requirements for the non-clinical testing of a SBP,
unless triggered by results of the repeat dose toxicity study or the local tolerance study and/or by
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other known toxicological properties of the RBP (e.g. known adverse effects of the RBP on
reproductive function).
10 Clinical evaluation
The main/pivotal clinical data should be generated using the product derived from the final
manufacturing process and therefore reflecting the product for which marketing authorization is
being sought. Any deviation from this recommendation needs to be justified and additional data
may be required, such as from PK bridging studies comparing the PK profiles of the products
from the previous and final formulations. For changes in the manufacturing process ICH Q5E
should be followed 7.
Clinical studies should be designed to demonstrate comparable safety and efficacy of the SBP to
the RBP and therefore need to employ testing strategies that are sensitive enough to detect
relevant differences between the products, if present (see below).
The clinical comparability exercise is a stepwise procedure that should begin with
pharmacokinetic and pharmacodynamic studies followed by the pivotal clinical trials. If at any
step relevant differences between the SBP and the RBP are detected, the reasons need to be
explored and justified. If this is not possible, the new product may not qualify as a SBP and a full
licensing (stand alone) application should be considered.
10.1 Pharmacokinetic (PK) studies
The PK profile is an essential part of the basic description of a medicinal product and should
always be investigated. PK studies should generally be performed for the routes of
administration applied for and using doses within the therapeutic dose range recommended for
the RBP.
PK studies must be comparative in nature and should be designed to enable detection of potential
differences between the SBP and the chosen RBP. This is usually best achieved by performing
single-dose, cross-over PK studies in a homogenous study population and by using a dose where
the sensitivity to detect differences is largest. For example, for a medicinal product with
saturable absorption (saturation kinetics), the lowest therapeutic dose would be most appropriate,
provided that the employed assay can measure the resulting drug plasma levels with sufficient
accuracy and precision. In order to reduce variability not related to differences between products,
PK studies could be performed in healthy volunteers, if considered ethical and scientifically
justified. If the investigated drug substance is known to have adverse effects and the
pharmacological effects or risks are considered unacceptable for healthy volunteers, it may be
necessary to perform the PK studies in the proposed patient population.
In general, single dose PK studies will suffice. However, in cases of dose or time-dependent
pharmacokinetics, resulting in markedly higher concentrations at steady-state than expected from
single dose data, a potential difference in the extent of absorption of the SBP and RBP may be
larger at steady-state than after single dose administration. In such cases, it may be advisable for
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the manufacturer to perform an additional comparative multiple dose study to ensure similar PK
profiles also at steady-state before commencing the confirmatory clinical trial(s). In steady-state
PK studies, the administration scheme should preferably use the highest customary dosage
recommended for the RBP.
The choice of single-dose studies, steady-state studies, or repeated determination of PK
parameters and the study population should be justified by the manufacturer. The cross-over
design eliminates inter-subject variability and therefore, compared to the parallel design, reduces
the sample size necessary to show equivalent PK profiles of the SBP and RBP. The treatment
phases should be separated by an adequate wash-out phase to avoid carry-over effects. The
cross-over design may not be appropriate for biological medicinal products with a long half-life
or for proteins for which formation of anti-product antibodies is likely. In parallel designs, care
should be taken to avoid relevant imbalances in all prognostic variables between treatment
groups that may affect the pharmacokinetics of the drug substance (e.g. ethnic origin, smoking
status, extensive/ poor metabolizer status of the study population).
PK comparison of the SBP and the RBP should not only include absorption/ bioavailability but
should also include elimination characteristics; i.e. clearance and/or elimination half-life, since
differences in elimination rate of the SBP and the RBP may exist.
Acceptance criteria for the demonstration of similar PK between the SBP and the RBP should be
pre-defined and appropriately justified. It is noted that the criteria used in standard clinical PK
comparability studies (bioequivalence studies) were developed for chemically-derived, orally
administered products and may not necessarily be applicable for biological medicinal products.
Due to the lack of established acceptance criteria designed for biologicals, the traditional 80-125 % equivalence range is often used. However, if the 90% confidence intervals of the ratio of
the population geometric means (test/ reference) for the main parameters under consideration
(usually rate and extent of absorption) fall outside this traditional range, the SBP may still be
considered similar to the RBP provided there is sufficient evidence for similarity from the quality,
non-clinical, PD, efficacy and safety comparisons.
Other PK studies, such as interaction studies (with drugs likely to be used concomitantly) or
studies in special populations (e.g. children, the elderly and patients with renal or hepatic
insufficiency) are not usually required for a SBP.
Historically, the PK evaluation of peptide or protein products has suffered from limitations in the
assay methodology thus limiting the usefulness of such studies. Special emphasis should
therefore be given to the analytical method selected and its capability to detect and follow the
time course of the protein (the parent molecule and/or degradation products) in a complex
biological matrix that contains many other proteins. The method should be optimized to have
satisfactory specificity, sensitivity and a range of quantification with adequate accuracy and
precision.
In some cases, the presence of measurable concentrations of endogenous protein may
substantially affect the measurement of the concentration-time profile of the administered
exogenous protein. In such cases, the manufacturer should describe and justify the approach to
minimize the influence of the endogenous protein on the results.
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10.2 Pharmacodynamic (PD) studies
Although comparative clinical trials are usually required for demonstration of similar efficacy
and safety of the SBP and RBP, it may be advisable for the manufacturer to ensure similar PD
profiles before proceeding to clinical trials, particularly if a difference in PK profiles of unknown
clinical relevance has been detected.
In many cases, PD parameters are investigated in the context of combined PK/PD studies. Such
studies may provide useful information on the relationship between dose/exposure and effect,
particularly if performed at different dose levels. In the comparative PD studies, PD effects
should be investigated in a suitable population using a dose/doses within the steep part of the
dose-response curve in order to best detect potential differences between the SBP and the RBP.
PD markers should be selected based on their clinical relevance.
10.3 Confirmatory pharmacokinetic/pharmacodynamic (PK/PD) studies
Usually, clinical trials are required to demonstrate similar efficacy between the SBP and the RBP.
In certain cases, however, comparative PK/PD studies may be appropriate, provided that 1) the
PK and PD properties of the RBP are well characterized, 2) at least one PD marker is a marker
linked to efficacy (e.g. an accepted surrogate marker for efficacy), and 3) the relationship
between dose/exposure, the relevant PD marker(s) and response/efficacy of the RBP is
established. Euglycaemic clamp studies would be an example for acceptable confirmatory
PK/PD studies for the comparison of efficacy of two insulins. In addition, absolute neutrophil
count and CD34+ cell count are the relevant PD markers for the activity of granulocyte colony
stimulating factor (G-CSF) and could be used in PK/PD studies in healthy volunteers to
demonstrate similar efficacy of two G-CSF-containing medicinal products.
The study population and dosage should represent a test system that is known to be sensitive to
detect potential differences between the SBP and the RBP. For example, in the case of insulin,
the study population should consist of non-obese healthy volunteers or patients with type 1
diabetes rather than insulin-resistant obese patients with type 2 diabetes. Otherwise, it will be
necessary to investigate a relevant dose range to demonstrate that the test system is
discriminatory 8. In addition, the acceptance ranges for demonstration of similarity in
confirmatory PK and PD parameters should be pre-defined and appropriately justified. If
appropriately designed and performed such PK/PD studies are often more sensitive to detect
potential differences in efficacy than trials using clinical endpoints.
10.4 Efficacy studies
Dose finding studies are not required for a SBP. Demonstration of comparable potency, PK and
PD profiles provide the basis for the use of the posology of the RBP in the confirmatory clinical
trial(s).
Similar efficacy of the SBP and the chosen RBP will usually have to be demonstrated in
adequately powered, randomized, and controlled clinical trial(s). The principles of such trials are
laid down in relevant ICH guidelines 8, 9. Clinical studies should preferably be double-blind or at a
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minimum observer-blind. In the absence of any blinding, careful justification will be required to
prove that the trial results are free from significant bias.
Potential differences between the SBP and the RBP should be investigated in a sensitive and
preferably well-established clinical model. For example, in the case of growth hormone (GH),
treatment-naïve children with GH deficiency usually represent the most appropriate study
population as opposed to children with non GH-deficient short stature that are usually less
sensitive to the effects of GH. Although adult patients with GH deficiency could also be
considered a “sensitive” population, the endpoint used to measure effects of GH treatment (i.e.
body composition) is less sensitive than the one used in children (i.e. longitudinal growth)
making an equivalence or non-inferiority margin more difficult to define.
In principle, equivalence designs (requiring lower and upper comparability margins) are clearly
preferred for the comparison of efficacy and safety of the SBP with the RBP. Non-inferiority
designs (requiring only one margin) may be considered if appropriately justified. While both of
the designs can be used, their advantages and disadvantages should be well understood. The
designs should be chosen regarding the possible advantages and disadvantages of each (see
section "Advantages and disadvantages of equivalence/ non-inferiority designs for SBPs"). For
statistical considerations see section “Statistical considerations for the design and analysis of
equivalence/ non-inferiority trials for SBPs” below.
Equivalence/ non-inferiority margins have to be pre-specified and justified based on clinical
relevance; i.e. the selected margin should represent the largest difference in efficacy that would
not matter in clinical practice. Treatment differences within this margin would thus, by definition,
be acceptable because they have no clinical relevance.
Similar efficacy implies that similar treatment effects can be achieved when using the same
dosage(s); in the head-to-head comparative trial(s), the same dosage(s) should be used for both
the SBP and RBP. In cases for which the medicinal product is titrated according to treatment
response (e.g. epoetin, insulin) rather than given at a fixed dosage (e.g. somatropin in GH-deficient children), equivalence/ non-inferiority should be demonstrated not only with regard to
treatment response but also with regard to dosage. This is best achieved by defining co-primary
endpoints that also include dosage.
Generally, equivalence trials are clearly preferable to ensure that the SBP is not clinically less or
more effective than the RBP when used at the same dosage(s). For medicinal products with a
wide safety margin, non-inferiority trials may also be acceptable. It should, however, be
considered that non-inferior efficacy, by definition, does not exclude the possibility of superior
efficacy of the SBP compared to the RBP which, if clinically relevant, would contradict the
principle of similarity.
Therefore, prior to initiating the confirmatory clinical trial, all comparative data generated
between the SBP and RBP up to this point should be carefully reviewed and analysed to
ascertain similarity of the SBP and the RBP. The confirmatory trial marks the last step of the
comparability exercise and prior demonstration of similar physicochemical characteristics,
potency and PK/PD profiles make superior efficacy of the SBP compared to the RBP highly
unlikely. However, in the rare event that, after completion of the study, the results would indeed
indicate statistically superior efficacy it should be excluded that this superiority is clinically
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meaningful and could be associated with increased adverse events if the SBP is prescribed at the
same dosage as the RBP. In the case of an equivalence trial clinically meaningful differences,
including superior efficacy, between the SBP and the RBP are excluded if the 95% confidence
interval of the treatment difference is fully contained within the pre-specified two-sided (upper
and lower) comparability margins. In the case of a non-inferiority trial, a post-hoc justification
that superior efficacy, if observed, is not clinically meaningful may be more difficult.
Whatever the pre-defined study design, the real results obtained from the clinical trial(s) will
determine whether the SBP and the RBP can be considered clinically similar. If clinically
relevant differences are found, the new product should not be considered similar to the RBP and
should be developed as a stand alone product.
Whereas several examples exist for licensing of SBPs based on equivalence trials (e.g.
recombinant human GH, epoetin and G-CSF in the EU), experience with non-inferiority trials for
this purpose is limited and mainly based on theoretical considerations. An additional advantage
of demonstration of equivalent efficacy (rather than non-inferior efficacy) is that this would
provide a stronger rationale for the possibility of extrapolation of efficacy data to other
indications of the RBP, particularly if these include different dosages than the one(s) tested in the
clinical trial (see section 10.7).
Advantages and disadvantages of equivalence/ non-inferiority designs for
SBPs
An equivalence trial is designed to confirm the absence of a clinically meaningful difference
between the SBP and the RBP. This is the most suitable design for confirming that SBP is
equivalent to the RBP which is in line with the principle of similarity since a non-inferiority trial
does not exclude the possibility that the SBP is shown to be statistically and clinically superior to
the RBP which contradicts the principle of similarity. The following table highlights the
advantages and disadvantages of each design.
Design
Equivalence
Advantages
Demonstration of equivalence
provides a strong rationale for the
possibility of extrapolation of
efficacy to other indications of the
RBP
Disadvantages
An equivalence trial tends to need a
larger sample size to achieve the same
study power as a non-inferiority trial
A finding of superiority would lead to
the failure of the equivalence trial.
Current experience for the There would be no option to show that
licensing of SBPs is based on the superiority observed is not
equivalence trials clinically relevant. However, a stand
alone application might still be an
option subject to a requirement for
additional studies
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Non-inferiority A non-inferiority trial requires a
smaller sample size to achieve the
same study power as an
equivalence trial.
Post-hoc justification that a finding of
statistically superior efficacy is not
clinically relevant is difficult. If the
superiority observed is considered
clinically relevant, then the SBP would
A finding of superiority of the
not be considered similar to the RBP
SBP compared to the RBP would
and should be developed as a stand
not lead to failure of a non-alone product.
inferiority trial, provided it can be
demonstrated that the superiority Demonstration that superior efficacy of
observed is not clinically relevant. the SBP is not associated with
increased adverse events if the SBP is
prescribed at the same dosage as the
RBP would be required in all cases.
Demonstration of non-inferiority does
not provide a strong rationale for the
possibility of extrapolation to other
indications of the RBP.
There is currently no experience with
licensing of SBPs based on non-inferiority trials.
Statistical considerations for the design and analysis of equivalence/ non-inferiority trials for SBPs
As indicated above, equivalence or non-inferiority studies may be acceptable for the comparison
of efficacy and safety of the SBP with the RBP. The choice of the clinical trial design will
depend on the product in question, its intended use, disease prevalence and the target population.
The specific design selected for a particular study should be clearly stated in the trial protocol
and justified. The statistical issues involved in designing, analysing and interpreting equivalence
and non-inferiority trials are complex and often very subtle. This section is intended to
emphasize the importance of the points that need to be considered in designing and analysing
equivalence and non-inferiority trials and does not provide a comprehensive overview of all
statistical considerations. In particular, a good understanding of statistical confidence intervals
and their application to equivalence and non-inferiority clinical trials is essential.
Irrespective of the trial design selected, a comparability margin should be specified during trial
design and clearly documented in the study protocol. For an equivalence trial, both the lower and
upper equivalence margins are required, while only one margin is required for a non-inferiority
trial. The selection of the margin should be given careful consideration and should be justified
both statistically and clinically. Adequate evidence of the effect size of the RBP should be
provided to support the proposed margin. The magnitude and variability of the effect size of the
RBP derived from historical trials should also be taken into consideration in determining the
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comparability margin both in terms of the endpoint chosen and the population to be studied. It
must be reasonably assured that if a difference between the RBP and SBP exists, then the study
is capable of showing that difference (this is referred to as “assay sensitivity”).
Statistical analysis for both equivalence and non-inferiority designs is generally based on the use
of two sided confidence intervals (typically at the 95% level) for the difference between
treatments. For equivalence trials, equivalence is demonstrated when the entire confidence
interval falls within the lower and upper equivalence margins. Non-inferiority evaluations are
one sided and statistical inference is based only on the lower or upper confidence limit,
whichever is appropriate for a given study. For example, if a lower margin is defined, non-inferiority is demonstrated when the lower limit of the confidence interval is above the non-inferiority margin. Analysis of non-inferiority trials can also be based on a one-sided confidence
interval at the 97.5% level.
Details of the sample size calculations should be provided in the study protocol. The basis of
estimates of any quantities used in the sample size calculation should also be clearly explained,
and these estimates will usually be based on results from earlier trials with the RBP or published
literature. Since the formulae for sample size calculations are slightly different between
equivalence and non-inferiority trials, and the two sided equivalence trial tends to need a larger
sample size than a one sided non-inferiority trial, sample size calculations should be based on
methods specifically designed for equivalence or non-inferiority trials. When estimating the
sample size for equivalence or non-inferiority trials it is usually assumed that there is no
difference between SBP and RBP. An equivalence trial could be underpowered if the true
difference is not zero. Similarly, a non-inferiority trial could be underpowered if the SBP is
actually less effective than the RBP. Determination of the appropriate sample size is dependent
on various factors including: the type of primary endpoint (e.g. binary, quantitative, time-to-event etc.), the pre-defined comparability margin, the probability of a type I error (falsely
rejecting the null hypothesis) and the probability of a type II error (erroneously failing to reject
the null hypothesis). Keeping the probability of a type II error low will increase the ability of the
study to show equivalence or non-inferiority of the SBP to the RBP. The expected rates of
patient dropouts and withdrawals should also be taken into consideration in the determination of
the sample size.
10.5 Safety
Pre-licensing safety data should be obtained in a sufficient number of patients to characterize the
safety profile of the SBP. Depending on their size and duration, efficacy trials may be sufficient
or may need to be extended to provide an adequate safety database. Comparison with the RBP
should include type, frequency and severity of adverse events/reactions. For cases in which
similar efficacy is demonstrated in confirmatory PK/PD studies but safety data relevant for the
target population cannot be deduced from these studies, safety data in the target population are
still needed. For example, for two soluble insulins, the euglycaemic clamp study is considered
the most sensitive method to detect differences in efficacy. However, immunogenicity and local
tolerance of subcutaneously administered SBP cannot be assessed in such a study and should
therefore be evaluated in the target population.
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Safety data should preferably be comparative. Comparison with an external control group is
usually hampered by differences in the investigated patient population and concomitant therapy,
observation period and/or reporting.
Safety data obtained from the clinical trials can be expected to mainly detect frequent and short-term adverse events/reactions. Such data are usually sufficient pre-licensing, but further close
monitoring of clinical safety of the SBP is usually necessary in the post-marketing phase (see
section 11).
10.6 Immunogenicity
Immunogenicity of biotherapeutic products should always be investigated pre-authorization.
Even if efficacy and safety of a SBP and RBP have been shown to be similar, immunogenicity
may still be different.
The immune response against a biotherapeutic is influenced by many factors such as the nature
of the drug substance, product- and process-related impurities, excipients and stability of the
product, route of administration, dosing regimen, and patient-, disease- and/or therapy-related
factors 10.
The consequences of unwanted immunogenicity may vary considerably, ranging from clinically
irrelevant to serious and life-threatening. Although neutralizing antibodies directly alter the
pharmacodynamic effect of a product (i.e. by directly blocking active site of the protein), binding
antibodies often affect pharmacokinetics and thereby also influence pharmacodynamics. Thus, an
altered effect of the product due to anti-product antibody formation might be a composite of
pharmacokinetic, pharmacodynamic and safety effects.
Immunogenicity of a biotherapeutic should always be investigated in humans since animal data
are usually not predictive of the immune response in humans. The frequency and type of
antibodies induced as well as possible clinical consequences of the immune response should be
compared for the SBP and the RBP. Comparison with an external control group is not considered
appropriate because this is usually hampered by differences in the investigated patient population,
observation period, sampling time points, assays employed, and interpretation of results.
Generally, the amount of immunogenicity data obtained from the comparative efficacy trial(s)
(i.e. trials that are powered for their primary efficacy endpoint) will allow detection of a marked
increase in immunogenicity of the SBP compared to the RBP and will be sufficient pre-licensing.
Where clinically meaningful or even serious antibody development has been encountered with
the RBP or the substance class but is too rare to be captured pre-licensing (e.g. cross-reacting
neutralizing anti-epoetin antibodies causing pure red cell aplasia), a specific risk management
plan (RMP) for the SBP may be necessary to assess this specific risk post-marketing (see section
11). In case similar efficacy is demonstrated in confirmatory PK/PD study(ies), immunogenicity
data in the target population are still needed (see section 10.5). If the manufacturer intends to
extrapolate efficacy and safety data to other approved indications of the RBP (see section 10.7),
care should be taken to ensure that immunogenicity is investigated in the patient population that
carries the highest risk of an immune response and immune-related adverse events.
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The manufacturer will need to justify their antibody testing strategy including the selection,
assessment, and characterization of assays, identification of appropriate sampling time points
including baseline, sample volumes and sample processing/storage as well as selection of
statistical methods for analysis of data. Antibody assays need to be validated for their intended
purpose. A screening assay of sufficient sensitivity should be used for antibody detection and a
neutralization assay should be available for further characterization of antibodies, if present.
Possible interference of the circulating antigen with the antibody assay(s) should be taken into
account. Detected antibodies need to be further characterized and their potential clinical
implications regarding safety, efficacy and pharmacokinetics evaluated. For example, the isotype
of the antibodies should be determined if they may be predictive of safety (e.g. development of
IgE antibodies correlates with the development of allergic and anaphylactic responses). If the
antibody incidence is higher with the use of the SBP compared to the RBP, the reason for the
difference needs to be investigated. Special attention should be paid to the possibility that the
immune response seriously affects the endogenous protein and its unique biological function.
The required observation period for immunogenicity testing will depend on the intended duration
of therapy and the expected time of antibody development and should be justified by the
manufacturer. In the case of chronic administration, one-year data will usually be appropriate
pre-licensing to assess antibody incidence and possible clinical implications. This is, for example,
the case for somatropin-containing products, where antibody development usually occurs within
the first 6-9 months of treatment but potential effects on growth would only be seen thereafter. In
some cases, shorter pre-licensing observation periods may be sufficient; e.g. for insulins, where
most susceptible patients will develop antibodies within the first 6 months of treatment and
clinical consequences, if any, would usually be observed around the same time as antibody
development. If considered clinically relevant, development of antibody titers, their persistence
over time, potential changes in the character of the antibody response and the possible clinical
implications should be assessed pre- and post-marketing.
Since pre-licensing immunogenicity data are often limited, further characterization of the
immunogenicity profile may be necessary post-marketing, particularly, if rare antibody-related
serious adverse events may occur that are not likely to be detected in the pre-marketing phase.
10.7 Extrapolation of efficacy and safety data to other clinical indications
If similar efficacy and safety of the SBP and RBP have been demonstrated for a particular
clinical indication, extrapolation of these data to other indications of the RBP (not studied in
independent clinical studies with the SBP) may be possible if all of the following conditions are
fulfilled:
• A sensitive clinical test model has been used that is able to detect potential differences
between the SBP and the RBP;
• The clinically relevant mechanism of action and/or involved receptor(s) are the same; e.g.
GH action in different conditions of short stature in children; erythropoiesis-stimulating action of
epoetins in different conditions associated with anaemia or for the purpose of autologous blood
donation. If the mechanism of action is different or not known a strong scientific rationale and
additional data (e.g. “PD fingerprint”, additional clinical data) will be needed;
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• Safety and immunogenicity of the SBP have been sufficiently characterized and there are
no unique/additional safety issues expected for the extrapolated indication(s), for which clinical
data on the SBP are not being provided; e.g. immunogenicity data in immunosuppressed patients
would not allow extrapolation to an indication in healthy subjects or patients with autoimmune
diseases while the reverse would be valid;
• If the efficacy trial used a non-inferiority study design and demonstrated acceptable
safety and efficacy of the SBP compared to the RBP, the applicant should provide convincing
arguments that this finding can be applied to the extrapolated indications; e.g. results from a non
inferiority trial in an indication where a low dose is used may be difficult to extrapolate to an
indication where a higher dose is used, from both efficacy and safety point of view.
If these prerequisites for extrapolation of efficacy and safety data of the SBP to other
indication(s) of the RBP are not fulfilled, the manufacturer will need to submit own clinical data
to support the desired indication(s).
If extrapolation of results from clinical studies for one indication to one or more different
indications is intended, a detailed scientific discussion on the benefit/ risk of such a proposal
should be provided based on the above criteria.
11 Pharmacovigilance
As for most biological medicines, data from pre-authorization clinical studies are usually too
limited to identify all potential unwanted effects of a SBP. In particular, rare adverse events are
unlikely to be encountered in the limited clinical trial populations being tested with the SBP.
Therefore, further close monitoring of the clinical safety of these products in all approved
indications and a continued benefit-risk assessment is necessary in the post-marketing phase.
The manufacturer should submit a safety specification and pharmacovigilance plan at the time of
submission of the marketing authorization application. The principles of pharmacovigilance
planning can be found in relevant guidelines such as ICH E2E 11. The safety specification should
describe important identified or potential safety issues for the RBP, the substance class and/or
any that are specific for the SBP. The pharmacovigilance plan should describe the planned post-marketing activities and methods based on the safety specification 11. In some cases, risk
minimization measures such as educational material for patients and/or treating physicians may
enhance the safe use of the SBP.
Any specific safety monitoring imposed on the RBP or product class should be incorporated into
the pharmacovigilance plan for the SBP, unless a compelling justification can be provided to
show that this is not necessary. Moreover, potential additional risks identified during the review
of the data obtained with the SBP should be subject to further safety monitoring (e.g. increased
immunogenicity that might result from a difference in the glycosylation profile).
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Post-marketing safety reports should include all information on product tolerability received by
the marketing authorization holder. The safety information must be evaluated in a scientific
manner and should include evaluation of the frequency and causality of adverse events.
Manufacturers should ensure that, at the time of the marketing authorization, they have in place
an appropriate pharmacovigilance system including the services of a qualified person responsible
for monitoring pharmacovigilance and the necessary means for the notification of adverse
reactions that occur in any of the countries where the product is marketed.
After the marketing authorization is granted, it is the responsibility of the NRA to closely
monitor the compliance of manufacturers with their marketing commitments, where appropriate,
and particularly with their pharmacovigilance obligations (as previously described).
In addition, as for all biotherapeutics, an adequate system is necessary to ensure specific
identification of the SBPs (i.e. traceability). The NRA shall provide a legal framework for proper
pharmacovigilance surveillance and ensure the ability to identify any biotherapeutics marketed in
their territory which is the subject of adverse reaction reports. This implies that an adverse
reaction report for any biotherapeutic should include, in addition to the International
Nonproprietary Names (INN) 12, other important indicators such as proprietary (brand) name,
manufacturer’s name, lot number and country of origin.
12 Prescribing information and label
The SBP should be clearly identifiable by a unique brand name. Where an INN is defined, this
should also be stated. WHO policy on INNs should be followed
(/medicines/services/inn/innquidance/en/). Provision of the lot
number is essential as this is an important part of production information and is critical for
traceability in cases where problems with a product are encountered.
The prescribing information for the SBP should be as similar as possible to that of the RBP
except for product-specific aspects, such as different excipient(s). This is particularly important
for posology and safety-related information, including contraindications, warnings and adverse
events. However, if the SBP has fewer indications than the RBP, the related text in various
sections may be omitted unless it is considered important to inform doctors and patients about
certain risks; e.g. because of potential off-label use. In such cases it should be clearly stated in
the prescribing information that the SBP is not indicated for use in the specific indication(s) and
the reasons why. The NRA may choose to mention the SBP nature of the product and the studies
that have been performed with the SBP including the specific RBP in the product information
and/or to include instructions for the prescribing physician on how to use SBP products.
13 Roles and responsibilities of NRAs
One of the responsibilities of a NRA is to set up appropriate regulatory oversight for the
licensing and post-marketing surveillance of SBPs that are developed and/or authorized for use
Page 30
in its area of jurisdiction. The experience and expertise of NRA in evaluating biotherapeutic
products is a key prerequisite for appropriate regulatory oversight of these products. The NRA is
responsible for determining a suitable regulatory framework for licensing SBPs. The NRA may
choose to utilize or amend existing pathways or develop a new pathway for this purpose.
As development of biotherapeutic products is a rapidly evolving area, regular review of the
NRAs for their licensing, the adequacy of the regulations for providing oversight, and the
processes and policies that constitute the regulatory framework is an essential component of a
well-functioning and up-to-date regulatory oversight for biotherapeutics.
A NRA may possess the regulatory authority for authorization of all new drugs and as such may
not need to amend its regulations to authorize SBPs. However, the EU has specifically amended
its regulations to provide an abbreviated regulatory pathway for SBPs (biosimilars) 13, 14, 15, 16. This
issue is subject of discussion in a number of other countries where development of SBPs is
ongoing. For instance, Health Canada and Japan have recently developed their guidelines for
manufacturers, and national guidelines are in development in some other countries. The
historical perspective of US FDA on the assessment of follow-on protein products has also been
published 17. In most instances, NRAs will need to provide guidance to manufacturers on the
information needed and regulatory requirements for the authorization of SBPs. A majority of
countries will either be using their existing legislation and applicable regulations or they will
amend or develop entirely novel frameworks for the authorization of SBPs. In some jurisdictions,
regulations for licensing subsequent entry versions of biotherapeutic products are intricately
linked with policies for innovation. Hence a NRA may need to coordinate with other
stakeholders for consistency.
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31
Authors and acknowledgements
The scientific basis for the evaluation and regulation of similar biotherapeutic products was
discussed and agreement for developing WHO Guidelines reached at the first WHO Informal
Consultation on Regulatory Evaluation of Therapeutic Biological Medicinal Products held in
Geneva, 19-20 April 2007, attended by the following participants:
Dr A. Bristow, Dr E. Gray, Dr R. Thorpe, and Dr J. S. Robertson, National Institute for
Biological Standardization and Control, Potters Bar, London, UK; Dr M. Cheraghali, Iran Blood
Transfusion Organization, Tehran, Iran; Dr L. G. Castanheira and Dr G. Garcia de Oliveira,
Agencia Nacional da Vigilancia Sanitaria, Brasília, Brazil; Dr E. Griffiths and Dr K. Nyarko,
Health Canada, Ottawa, Canada; Dr U. Kalinke, Paul-Ehrlich-Institut, Langen, Germany; Dr T.
Kawanishi and Dr T. Yamaguchi, National Institute for Health and Science, Tokyo, Japan; Dr J.
C. Krayenbühl and Ms M. Schmid-Appert, Swissmedic, Bern, Switzerland; Ms M. Poulis,
Therapeutic Goods Administration, Wooden, Australia; Dr H. Schellekens, Utrecht University,
Utrecht, Netherlands; Dr Y. Sohn, Korea Food and Drug Administration, Seoul, Republic of
Korea; Dr J. Southern, Ministry of Health, CapeTown, South Africa; Dr K. Webber, Food and
Drug Administration, Silverspring, Maryland, USA; Dr M. Weise, Federal Institute for Drugs
and Medical Devices, Bonn, Germany; Dr P. J. Gogoi, Ministry of Health & Family Welfare,
Guwahati, India; Dr W. Junzhi, National Institute for the Control of Pharmaceutical and
Biological Products, Beijing, China; Dr P. Richardson, European Medicines Agency, London,
UK; Dr S. Gairola, Serum Institute of India Ltd, Pune, India, Representative of the Developing
Country Vaccine Manufacturing Network (DVCMN); Dr J. Mascaro, Hoffman La Roche, Basel,
Switzerland, Representative of the International Federation of Pharmaceutical Manufacturers and
Associations (IFPMA); Dr A. Fox, Amgen, Cambridge, UK, Representative of IFPMA; Dr R.
Krause, IFPMA, Geneva, Switzerland; Dr M. Schiestl, Sandoz, Kundl/ Tirol, Austria,
Representative of the European Generic medicines Association (EGA); Ms S. Kox, EGA,
Brussels, Belgium; Dr A. Eshkol, International Association for Biologicals (IABS), Geneva,
Switzerland; Dr R. Balocco-Mattavelli, Dr S. Lasseur, Dr J. Dong, Quality Assurance and Safety
of Medicines unit, Medicines Policy and Standards Department, World Health Organization,
Geneva, Switzerland; Dr D. Wood, Dr I. Knezevic and Dr J. Joung, FCH/IVB/QSS, World
Health Organization, Geneva, Switzerland.
The first draft of the guidelines was developed by the members of the WHO drafting group on
similar biotherapeutic products following the meeting held at the Federal Institute for Drugs and
Medical devices (BfArM), Bonn, Germany, on 5 - 7 March 2008, attended by:
Dr Elwyn Griffiths and Dr Kwasi Nyarko, Biologics and Genetic Therapies Direcctorate, Health
Canada, Ottawa, Canada; Dr Hans-Karl Heim and Dr Martina Weise, Federal Institute for
Drugs and Medical Devices (BfArM), Bonn, Germany; Dr Yeowon Sohn, Korea Food and Drug
Administration, Seoul, Republic of Korea; Dr Ivana Knezevic and Dr Jeewon Joung,
FCH/IVB/QSS, World Health Organization, Geneva, Switzerland.
The second draft of these guidelines (BS/08.2101) was prepared by Dr Elwyn Griffiths and Dr
Kwasi Nyarko, Biologics and Genetic Therapies Directorate, Health Canada, Ottawa, Canada;
Dr Martina Weise, Federal Institute for Drugs and Medical Devices (BfArM), Bonn, Germany;
Dr Ivana Knezevic and Dr Jeewon Joung, FCH/IVB/QSS, World Health Organization, Geneva,
Page 32
Switzerland, after a WHO Informal Consultation on Regulatory Evaluation of Therapeutic
Biological Medicines in Seoul, Republic of Korea, 27-29 May, 2008, and acknowledgements are
due to the following participants:
Dr R. Thorpe and Dr M. Wadhwa, National Institute for Biological Standardization and Control,
Potters Bar, London, UK; Dr M. Cheraghali, Iran Blood Transfusion Organization, Tehran, Iran;
Dr P. Thanaphollert, Food and Drug Administration, Nonthaburi, Thailand; Dr E. Griffiths and
Dr K. Nyarko, Health Canada, Ottawa, Canada; Dr T. Yamaguchi, National Institute for Health
and Science, Tokyo, Japan; Dr Y. Sohn and Dr S. Hong, Korea Food and Drug Administration,
Seoul, Republic of Korea; Dr J. Southern, Ministry of Health, CapeTown, South Africa; Dr E.
Shacter, Food and Drug Administration, Bethesda, Maryland, USA; Dr M. Weise and Dr H.
Heim, Federal Institute for Drugs and Medical Devices, Bonn, Germany; Dr P. J. Gogoi,
Ministry of Health & Family Welfare, Guwahati, India; Dr W. Junzhi, National Institute for the
Control of Pharmaceutical and Biological Products, Beijing, China; Dr P. Richardson, European
Medicines Agency, London, UK; Dr S. Gairola, Serum Institute of India Ltd, Pune, India,
Representative of DCVMN; Dr H. Ji, LG life Science, Seoul, Republic of Korea, representative
of DCVMN; Dr J. Mascaro, Hoffman La Roche, Basel, Switzerland, Representative of IFPMA;
Dr A. Fox, Amgen, Cambridge, UK, Representative of IFPMA; Dr R. Krause, IFPMA, Geneva,
Switzerland; Dr M. Schiestl, Sandoz, Kundl/Tirol, Austria, Representative of EGA; Dr S. Eisen,
TEVA, London, UK, representative of EGA; Ms S. Kox, EGA, Brussels, Belgium; Dr M. L.
Pombo, Pan American Health Organization, Washington DC, USA; Dr I. Knezevic and Dr
Jeewon Joung, FCH/IVB/QSS, World Health Organization, Geneva, Switzerland.
Taking into account comments and advise provided by the ECBS on the BS/08.2101, the third
draft was prepared by the drafting group members following the meeting in Tokyo, Japan, 16
and 18 February, 2009, attended by:
Dr Seung Hwa Hong and Dr Jeewon Joung, Korea Food and Drug Administration, Seoul,
Republic of Korea; Dr Kwasi Nyarko, Biologics and Genetic Therapies Directorate, Health
Canada, Ottawa, Canada; Dr Peter Richardson, European Medicines Agency (EMEA), Quality
of Medicines Sector, London, UK; Dr Emily Shacter and Dr Keith Webber, Food and Drug
Administration, Bethesda, Maryland, USA; Dr Martina Weise, Federal Institute for Drugs and
Medical Devices (BfArM), Bonn, Germany; Dr Teruhide Yamaguchi, National Institute of
Health Sciences, Japan; Dr Ivana Knezevic and Dr Hye-Na Kang, FCH/IVB/QSS, World Health
Organization, Geneva, Switzerland.
The forth draft of these revised guidelines was prepared by Dr Elwyn Griffiths, Dr Catherine
Njue, and Dr Kwasi Nyarko, Biologics and Genetic Therapies Directorate, Health Canada,
Ottawa, Canada; Dr Hans-Karl Heim and Dr Martina Weise, Federal Institute for Drugs and
Medical Devices (BfArM), Bonn, Germany; Dr Jeewon Joung, Korea Food and Drug
Administration, Seoul, Republic of Korea; Dr Teruhide Yamaguchi, National Institute of Health
Sciences, Japan; Dr Ivana Knezevic and Dr Hye-Na Kang, FCH/IVB/QSS, World Health
Organization, Geneva, Switzerland, after a WHO/HC Consultation on Regulatory Considerations
in Evaluating Similar Biotherapeutic Products in Ottawa, Canada, 15-17 July, 2009, and
acknowledgements are due to the following participants:
Page
33
Mrs A. Abas, Ministry of Health Malaysia, Jalan University, Selangor, Malaysia; Dr K. Baek,
Korea Food and Drug Administration, Seoul, Republic of Korea; Dr S. Kozlowski,
FDA/CDER/OPS, Bethesda, MD, USA; Dr H. M. J. Leng, School of Pharmacy University of the
Western Cape, South Africa; Dr J. Luo, States Food and Drug Administration (SFDA), Beijing,
People's Republic of China; Mrs Y. H. Nunez, Centro para el Control Estatal de la Calidad de los
Medicamentos (CECMED), Habana, Cuba; Dr S. Shani, Ministry of Health and Social Welfare
Government of India FDA, New Delhi, India, Dr K. Shokraie, Food and Drug Ministry of Health,
Tehran, Iran; Dr K. Tungsanga, Chulalongkorn University, Bangkok, Thailand; Dr J. Wang,
National Institute for the Control of Pharmaceutical & Biological Products, Beijing, People's
Republic of China; Ms M. Chultem, Dr A. Klein, Dr A. Ridgway, and Dr J. Wang, Biologics and
Genetic Therapies Directorate, Health Canada, Ottawa, Canada; Dr H. Malhotra, SMS Medical
College Hospital, Jaipur, India, Representative of DCVMN; Dr P. D. Picon, Federal University
of Rio Grande do Sul, Rio Grande do Sul, Brazil, Representative of DCVMN; Dr J. Mascaro,
Elan Pharma International, Ireland, Representative of IFPMA; Dr A. Fox, Amgen, Cambridge,
UK, Representative of IFPMA; Dr S. Day, Roche Products Ltd, Hertfordshire, UK,
Representative of IFPMA; Dr M. Fletcher, Pfizer Global R&D, New London, USA,
Representative of IFPMA; Dr S. Eisen, TEVA, London, UK, representative of EGA; Dr I.
Ahmed, Hospira, IL, USA, Representative of EGA; Dr S. Balser, Sandoz Biopharmaceuticals,
Oberhaching, Germany, Representative of EGA; Dr. R. Krause, IFPMA, Geneva, Switzerland,
Representative of IABS.
Document WHO/BS/09.2110 was prepared by Dr Ivana Knezevic and Dr Hye-Na Kang, WHO
for consideration by the sixtieth meeting of the Expert Committee on Biological Standardization,
held in Geneva in 2009. Further changes were made to WHO/BS/09.2110 by the Expert
Committee on Biological Standardization, resulting in the present document. Special thanks for
Dr Catherine Njue, Health Canada, Ottawa, Canada and Dr Marie Bielsky, Medicines and
Healthcare products Regulatory Agency, London, UK for their comments and advice during the
ECBS meeting.
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