Scientific Research to Support the Regulation of 
Subsequent Entry (follow-on) Biologics: 
Philosophy and Practice. 

a presentation by
Dr. Mary Alice Hefford, Health Canada (biography) 
at the Barnett Institute, Northeastern University 7 October 2008
(summary by Roger Kautz, Barnett Institute staff)

Many issues are raised with the introduction of generic protein pharmaceuticals, called "Biosimilars" in the US, "Follow-on Biologicals" (FOB's) in Europe, and "Subsequent Entry Biologicals"  (SEB's) in Canada.  (see the Biogenerics2008 website).   There is an expectation, because the parent drug has already undergone clinical testing and approval, that this would reduce the price of introducing an SEB.  But biologicals are inherently heterogeneous in both their structure and their efficacy.    

OUTLINE

Health Canada
Regulatory research - its different philosophy
Scientific questions about regulation of SEB's
Methods under investigation at Health Canada
Outstanding Research Issues

 

Health Canada

Health Canada can be thought of as the "Canadian FDA", but it has a significantly broader commission in the responsibility for the health and safety the population, regulating foods and  consumer goods as well as drugs.  It is also a provider of medical services like medicare, as well as stewarding the relevant industries and funding research.  

The Biologics and Genetic Therapies Division (BGTD) is about 400 people, mostly in evaluation.   65 staff in the Centre for Biologics Research (CBR), which is distinct from the Centre for Biologics Evaluation,  perform research in support of regulation.  The CBR has a dual mandate: in stewardship, to anticipate threats to health and provide scientific advice; and in regulation, to develop new analytical methods, including some postmarket analysis.  The CBR's role is not do evaluation itself, but to advise the evaluators.  

Regulatory Research

Regulatory research bears some distinctions from traditional basic, applied or academic research.  Regulatory research is at the crossroads between basic and applied research - deriving specific methods from broad knowledge, like applied research, but providing methods capable of radiating broad, generalizable knowledge useful to the regulators, applicants, or public.   

In contrast to academic research, which primarily seeks to invent new methods and sell them to the community, regulatory research is just as likely to adapt an old method as to invent a new.  Experiments are designed to show precisely what it can and cannot do, and to provide this information objectively, without exaggeration.  

Analytical Techniques for Evaluation of Subsequent Entry Biologics

The goal of analysis is to assure the SEB will function comparably as a drug, using predictive, physico-chemical, and clinical methods, but remembering that biologicals are inherently heterogeneous. Beyond confirming the primary sequence of the intended product, it is necessary to confirm correct folding, and characterize heterogeneity in posttranslational modifications (glycosylation, phosphorylation) and degradation (deamidation, oxidation).  Particularly important is the degree of aggregation.  Ideally  (although not feasible) one would like to know the stability and potency of all related products.  Analysis is both tempered and complicated by the facts that (i) one is establishing comparability, not equivalence, and (ii) one is comparing the formulated drug product, not the isolated drug substance.  Regulatory analysis typically includes

• Physical and chemical analyses
• Clinical trials or  "bridging studies" (smaller clinical trials to show similarity to the reference material)
• Literature reports and other public information on the innovator product.

The physical and chemical methods include:

• FTIR
• Thermal denaturation (using FTIR data)
• Circular dichroism
• Gel Electrophoresis 
• Chromatographic separations (LC) 
• Capillary Electrophoresis (CE) and its variants
• NMR Fingerprinting (proton/nitrogen correlations)
• Mass spectrometry

Although some impurities have adverse effects, many degradants are likely to occur in the body, even of the endogenous product the drug is based on.  Even when impurities are benign, however, variation in the impurities present is an important indicator of whether the manufacturer has an adequate degree of  process control.  

If you know what you are looking for, a good chemist can devise a targeted method to detect it.  An outstanding question is whether and how high-content analysis could be used to screen materials when you don't know what you're looking for, like oversulfated chondroitin in heparin, or melamine in  milk.  

Twenty years ago, when the original products were licensed, the regulatory agencies gave little information on how they came to their decision.  If they had, the re-licensors might well argue, for example, that if SDS-PAGE was good enough for the original product, it should be sufficient now.  The feeling of the regulators today, however, is that the "latest technology" should be required.   

Biophysical Methods for Higher Order Structure
FTIR is sensitive to secondary structure, spectra can be deconvoluted into the "fraction folded" (percentage native vs. denatured).  Thermal denaturation curves can be generated by taking IR spectra at a series of temperatures, to plot fraction folded vs. temperature.  It is highly reproducible, on material from the same manufacturer, but these "Tm curves" can shift significantly as a function of, for example, pH.  And the curves of rGH from different manufacturers do vary, as delivered, in both Tm and pH.  However, all are superimposable  if the excipients are exchanged, and the pH matched.  

NMR fingerprinting.  The "fingerprint" region of a proton-nitrogen 2D NMR spectrum (HSQC) provides an information-rich assessment of the protein conformation at each amino acid. These spectra can be acquired in a few hours or overnight.  Superimposing plots of an analyte and a reference material provides compelling evidence for or against similarity.  

Outstanding Research Issues

Quantification: how much of an impurity is present?  Quantitative methods are often labor-intensive.

Posttranslational modifications:  Need to determine the degree of heterogeneity, more than specifically what the modifications are.  

Can partial misfolding be detected?  CD and FTIR are bulk methods.  Can they detect 3% misfolding?  0.3%?   Can NMR?  This is being tested by generating mutant proteins with subtle or dramatic conformational differences, which can be mixed with the parent protein at various levels to determine the LOD of the different methods, for different degrees of misfolding.  

Can One "de-formulate"?
The SEB sponsor typically has to compare their drug substance with the innovator's substance purified from the off-the-shelf drug product.  Does removing  albumin, or other excipients, from a formulation change the structure of the therapeutic protein?  How can either the sponsor or the regulators prove it doesn't, if the presence of a 4-fold (or 50-fold) excess of albumin interferes with any any protein chemistry measurements of the drug product?  Is it meaningful to de-formulate, if the drug substance is not stable or has different activity in isolated form?
We are developing physicochemical assays which can use other chemical properties of the drug substance to confirm its structure and function in the formulated product. .

How similar is "similar enough" ?
If a difference is detected, what does it mean?  SEB's are by definition comparable, not identical.  Will a thorough analysis just detect a lot differences that don't matter physiologically?

Quality by Design
Manufacturers are designing quality into the process, implementing for examples process controls to monitor oxidation even during fermentation.  A mojor challenge to QBD is we don't know which variants can be tolerated, in what amounts.  Which glycoforms affect potency or safety? Can deamidated products be tolerated? Oxidized products?
   Towards QBD, we making variants chemically and testing, for example, the effects of oxidation.