Author byline as per print journal: Jon SB de Vlieger, PhD; Professor Gerrit Borchard, PharmD, PhD; Vinod P Shah, PhD; Beat Flühmann, PhD; Sesha Neervannan, PhD; Professor Stefan Mühlebach, PhD
Abstract: |
Submitted: 4 October 2016; Revised: 20 October 2016; Accepted: 24 October 2016; Published online first: 31 October 2016
It is with great interest that we read the publication entitled: ‘The EU is ready for non-biological complex medicinal products’ by Dr Falk Ehmann and Dr Ruben Pita published in GaBI Journal 2016 [1]. In this GaBI Journal paper the authors of the European Medicines Agency (EMA) express their personal view on the policies that the European Union (EU) and EMA have been developing with regard to the regulation of non-biological complex drug (NBCD) products in the EU and on a global scale. The full definition of NBCD products, among which a substantial number of nanomedicines are found, is stated in their paper. As the publication refers to several papers co-authored by us, please allow us to make some comments on the message presented by Drs Ehmann and Pita.
It is a laudable and appreciated initiative of the authors to provide their personal view on the regulatory aspects of NBCD products. The text clearly describes the current framework in which the EU and EMA operate, as well as the global initiatives to harmonize the regulation of NBCD products. However, we would like to ask that the authors consider some points to further the discussion regarding the suitability/degree of adaptation of this regulatory framework in practice and make some recommendations. Our comment is based on the fact that the debate on scientific evidence and understanding of these drugs of high complexity and their related in vivo profiles are still ongoing, which render the selection of appropriate evaluation tools difficult. In our comment we follow the same section headings as used by Ehmann and Pita.
Re: Marketing authorization procedures and the legal basis of submission
In several European countries, nano-similars (follow-on versions of nanomedicines and falling under the NBCD definition) have received marketing authorization following national procedures allowing for different appreciation of the complexity leading to different outcomes. Over time, the outcome of clinical studies from independent sources published in reputable journals became available [2–4]. They clearly showed differences in clinical performance between the innovator and follow-on products. Although these findings may have contributed to the generation of EMA referral and reflection papers [5, 6], it did not lead to clear actions of the competent authorities, e.g. to inform the medical community about therapeutic inequivalence. This aspect is of highest importance as such follow-on medicinal products are put on the market mainly to obtain established therapeutics in a ‘generic version’ allowing drug accessibility at a lower price. Given the assumed comparability of quality, safety and efficacy, substitution or interchange may be possible without notification of healthcare professionals or the patient. For NBCDs and their ‘similars’, this does not only interfere with traceability of the dispensed drug product but also has therapeutic consequences for the patient as clinical evidence has shown.
In our view, the approval process of follow-on versions of NBCD products should follow (being mandatory and not optional) the centralized procedure where the combined competence of the large network of EMA experts is directly available, as is the case for biosimilars. This approach guarantees the application of up-to-date scientific knowledge and evaluation tools. Moreover, drafting EMA reflection papers for the approval of NBCD product families such as liposomes, glatiramoids, iron-colloidals and others stimulates discussion and hopefully leads to the introduction of validated preclinical models and/or a request for the performance of clinical studies, if deemed necessary in NBCD guidance protocols. Last but not least, the outcome of independent research showing lack of equivalence of NBCD follow-on versions requires actions from the side of the competent authorities. For example, EMA may follow the example set by the US Food and Drug Administration (FDA) by performing Generic Drug User Fee Amendment (GDUFA) type programmes, including supporting scientific investigations on NBCD related topics [7].
Re: Harmonization of requirements across regions
Ehmann and Pita mention current initiatives to harmonize EMA and FDA technical requirements for follow-on medicinal products. For outsiders it is difficult to judge the extent of progress as little information is brought into the public domain. Both EMA and FDA claim that regulatory decisions regarding equivalence should have a strong science base. However, Lipodox, the follow-on version of Doxil (doxorubicin-liposomes) which received marketing approval in the US failed to do so in Europe. Another example is the follow-on versions of low-molecular weight heparins. They are not considered biologicals in the US, but are in Europe, where they are seen as biosimilars. Published reflection papers (EMA) and (draft) guidance documents (FDA) reflect close views from both sides of the Atlantic Ocean but are not always aligned [8, 9]. The World Health Organization (WHO) has taken the initiative to draft a WHO regulatory protocol for biosimilars [10], but has not started such an initiative for NBCD follow-on products. Ehmann and Pita mention other bodies as well (International Pharmaceutical Regulators Forum [IPRF] and International Council for Harmonisation of Technical Requirements for Pharmaceuticals for Human Use [ICH]), but no concrete results have been reported so far. The scientific basis for regulatory protocols for NBCD products should be further developed with a global discussion platform enabling an open exchange among experts in the field. Special emphasis should be put on the identification of the physicochemical parameters leading to clinically meaningful differences. In Europe, relevant clinical differences of the performance of supposedly equivalent nanomedicine follow-on products compared to the originator drug were described (see above). Very little, however, is known about the experience in other parts of the world. But would this problem be restricted to Europe? Very unlikely so! Here again, one should strive to create a database filled with data on the (pre)clinical outcome of therapy using NBCD follow-on products from all over the world, and published in reputable journals.
In our opinion, the title of the Ehmann and Pita article should be accompanied by a question mark. In principle, EMA may have the legal basis to deal with NBCD products and their follow-on versions, but in practice there is a list of desiderata. On the top of this list are: 1) Strengthening the science base in the public domain to demonstrate equivalence of these products, for Europe as well as for the rest of the world; 2) Taking appropriate actions and guidance when therapeutic inequivalence of products has been proven; 3) Intensifying global harmonization efforts of reflection papers/guidance documents; and 4) Assisting in and support of educational actions to spread awareness and increase knowledge on the topic especially towards healthcare professionals to eventually assure optimal patient benefit by rational and correct drug treatment.
In our view, a harmonized regulatory approval pathway similar to, but distinctly separate from, the ‘biosimilarity pathway’ should be considered. Because of the complex nature of NBCD products, a stepwise comparison of test to reference drug with respect to analytical characterization, animal studies and clinical studies is essential. This will facilitate the assessment of therapeutic interchangeability.
The views expressed are those of the authors and should not be understood or quoted as being made on behalf of or reflecting the position of the individual organizations or the NBCD Working Group as a whole.
Competing interests: Authors are Steering Committee members of the NBCD Working Group hosted at the Dutch not for profit organization Lygature, The Netherlands.
Provenance and peer review: Not commissioned; internally peer reviewed.
Jon SB de Vlieger, PhD
Lygature, 6 Jaarbeursplein, NL-3521 AL Utrecht, The Netherlands
Professor Gerrit Borchard, PharmD, PhD
School of Pharmaceutical Sciences, University of Geneva, University of Lausanne, 1 Rue Michel Servet, CH-1211 Geneva, Switzerland
Vinod P Shah, PhD
Pharmaceutical Consultant, 11309 Dunleith Place, North Potomac, MD 20878, USA
Beat Flühmann, PhD
Vifor Fresenius Medical Care Renal Pharma Ltd, 37 Rechenstrasse, PO Box, CH-9001 St Gallen, Switzerland
Sesha Neervannan, PhD
Allergan Plc, RD2-3 A, 2525 Dupont Drive, Irvine, CA 92612, USA
Professor Stefan Mühlebach, PhD
Vifor Pharma Ltd, 61 Flughofstrasse, PO Box, CH-8152 Glattbrugg, Switzerland
Department of Pharmaceutical Sciences, Pharmacenter, University of Basel, 50 Klingelbergstrasse, CH-4056 Basel, Switzerland
References
1. Ehmann F, Pita R. The EU is ready for non-biological complex medicinal products. Generics and Biosimilars Initiative Journal (GaBI Journal). 2016;5(1):30-5. doi:10.5639/gabij.2016.0501.008
2. Rottembourg J, Kadri A, Leonard E, Dansaert A, Lafuma A. Do two intravenous iron sucrose preparations have the same efficacy? Nephrol Dial Transplant. 2011;26(10):3262-7.
3. Martin-Malo A, Merino A, Carracedo J, et al. Effects of intravenous iron on mononuclear cells during the haemodialysis session. Nephrol Dial Transplant. 2012;27(6):2465-71.
4. Agüera ML, et al. Efficiency of original versus generic intravenous iron formulations in patients on haemodialysis. PLoS One. 2015;10(8): e0135967.
5. European Medicines Agency. Intravenous iron-containing medicinal products [homepage on the Internet]. [cited 2016 Oct 20]. Available from: http://www.ema.europa.eu/ema/index.jsp?curl=pages/medicines/human/referrals/Intravenous_iron-containing_medicinal_products/human_referral_000343.jsp&mid=WC0b01ac05805c516f
6. European Medicines Agency. Data requirements for intravenous iron-based nano-colloidal products developed with reference to an innovator medicinal product [homepage on the Internet]. [cited 2016 Oct 20]. Available from: http://www.ema.europa.eu/ema/index.jsp?curl=pages/regulation/general/general_content_001408.jsp&mid=WC0b01ac05806403e0
7. U.S. Food and Drug Administration. FY 2016 Regulatory Science Initiatives Part 15 Public Meeting [homepage on the Internet]. [cited 2016 Oct 20]. Available from: http://www.fda.gov/ForIndustry/UserFees/GenericDrugUserFees/ucm489572.htm
8. Authors are Steering Committee members of the NBCD Working Group hosted at the Dutch not for profit organization Lygature, the Netherlands. Generics and Biosimilars Initiative. EU guidelines for nanosimilars [www.gabionline.net]. Mol, Belgium: Pro Pharma Communications International; [cited 2016 Oct 20]. Available from: www.gabionline.net/Guidelines/EU-guidelines-for-nanosimilars
9. GaBI Online – Generics and Biosimilars Initiative. US guidelines for follow-on NBCDs [www.gabionline.net]. Mol, Belgium: Pro Pharma Communications International; [cited 2016 Oct 20]. Available from: www.gabionline.net/Non-Biological-Complex-Drugs/Guidelines/US-guidelines-for-follow-on-NBCDs
10. World Health Organization. Guidelines on evaluation of Similar Biotherapeutic Products (SBPs) [homepage on the Internet]. [cited 2016 Oct 20]. Available from: http://www.who.int/biologicals/areas/biological_therapeutics/BIOTHERAPEUTICS_FOR_WEB_22APRIL2010.pdf © World Health Organization 2009
Author for correspondence: Jon SB de Vlieger, PhD, Lygature, 6 Jaarbeursplein, NL-3521 AL Utrecht, The Netherlands |
Disclosure of Conflict of Interest Statement is available upon request.
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Source URL: https://gabi-journal.net/is-the-eu-ready-for-non-biological-complex-drug-products.html
Author byline as per print journal: Jon SB de Vlieger, PhD; Professor Stefan Mühlebach, PhD; Vinod P Shah, PhD; Scott E McNeil, PhD; Professor Gerrit Borchard, PharmD, PhD; Vera Weinstein, PhD; Beat Flühmann, PhD; Sesha Neervannan, PhD; Professor Daan JA Crommelin, PhD
Abstract: |
Submitted: 16 September 2015; Revised: 15 October 2015; Accepted: 19 October 2015; Published online first: 2 November 2015
The concept of non-biological complex drug (NBCD) products has been presented and discussed on several occasions in the GaBI Journal [1–4]. The growing interest in this topic in academic, industrial and regulatory circles led to the establishment of an Editorial Section on Non-Biological Complex Drugs in both the GaBI Journal and GaBI Online starting in the third quarter of 2015.
In 2011, the first publication on NBCDs appeared [5] as a result of a workshop held in Leiden, The Netherlands, in 2009. For the first time this class of drug products was identified and recognized. These products are more complex than small, low molecular drugs and as complex or even more complex than biologicals; sharing many of the characteristics of the latter category but not being derived from living sources. As a consequence, the authors argued that for the equivalence testing of NBCD follow-on products a regu latory pathway should be developed that was similar to the pathways developed by the European Medicines Agency (EMA) and later the US Food and Drug Administration (FDA) for approving biosimilars. This proposal was backed up by evidence provided by a (still growing) number of published studies on NBCD follow-on versions that were authorized using a ‘standard’ but inadequate generic assessment protocol.
A working group hosted by the Dutch Top Institute (TI) Pharma in Leiden was set up to raise awareness of the challenges NBCD products present worldwide, to stimulate the publication of scientific reports and discussions and to provide a rigorous, sciencebased, regulatory policy for NBCD products [6]. These efforts led to a number of publications and a book exclusively dedicated to the NBCD concept and its regulation. These publications provide a definition for NBCD products, discuss different classes of NBCDs, propose an overarching regulatory philosophy for evaluating NBCD follow-on versions and, finally, outline what issues are still unresolved [7–9].
This paper to the GaBI Journal further explains:
A definition of NBCD products that was published earlier by the NBCD working group reads: ‘A Non-Biological Complex Drug is a medicinal product, not being a biological medicine, where the active substance is not a homo-molecular structure, but consists of different (closely related and often nanoparticulate) structures that can’t be isolated and fully quantitated, characterized and/or described by stateof-the-art (physico)chemical analytical means and where the clinical meaning of the observed differences is not known. The composition, quality and in vivo performance of NBCDs are highly dependent on manufacturing processes of both the active ingredient as well as in most cases the formulation’ [7].
Present product ‘families’ and beyond
At present the following NBCD product groups or ‘families’ have been identified and discussed in the literature: liposomes, polymeric micelles, glatiramoids, iron-carbohydrate complexes, albuminanticancer drug nanoparticles and nanocrystals. The rapidly growing group of nanomedicines will add many NBCDs to this list [9–10]. Interestingly, there are also medicinal products such as the low molecular weight heparins (LMWHs) showing similar complexity but falling under different regulatory policies, i.e. by EMA LMWHs are seen as biologicals and by FDA as non-biologicals.
Over the last few years a number of studies on these NBCD product families have been published. This list is growing and expanding beyond only parenteral drugs. Recently, the present science base, including the: (1) chemistry and structure; (2) manufacturing; (3) (physico)chemical characterization; (4) pharmacology; and (5) regulatory status, of these product groups was reviewed in a book [9]. The availability of these data in the public domain should contribute to sciencebased discussions and could serve as a model to be followed for consideration of other NBCD product families. In addition, questions regarding interchangeability and substitutability of NBCD follow-on versions have important implications for the handling of such medicinal products by healthcare professionals. Requests are being made by these healthcare professionals for education on the topic of NBCDs and for further, tailor-made, reliable information for patients.
Other candidate NBCD product families that are waiting to be identified include emulsions (parenteral or ocular), dry powder inhalers and oral bioactive polymers such as complex phosphate binders.
The regulatory landscape
In earlier publications in GaBI Online the differences between the characteristics of small, low molecular weight molecules and biologicals were listed, see Table 1 [11]. If the items in the ‘biological drugs’ column (in italics) that relate to the biological source of the product and immunogenicity are removed, what remains demonstrates that there is a striking resemblance between the characteristics of biologicals and NBCD products.
Because of this similarity in product characteristics, the NBCD Working Group has proposed on several occasions that regulators should follow the same regulatory pathway for NBCD follow-on products as for biosimilars. This proposal is schematically shown in Figure 1 where ‘Totality of evidence’ is the key phrase when assessing therapeutic equivalence of NBCD innovator and follow-on products.
Neither FDA nor EMA uses special NBCD regulatory schemes. These agencies use existing pathways for the introduction of innovative and follow-on NBCD products. FDA uses the 505(b)(1)/505(b)(2) and 505(j) pathways for innovator products and follow-on versions, respectively. However, both FDA and EMA are paying increasing attention to regulatory issues related to NBCD families [12–13].
Generally speaking, there are two clearly distinct regulatory documents for these NBCD product families. On the one hand, FDA and/or EMA published ‘draft guidance’ and/or ‘reflection papers’ on new products such as liposomes [14], polymeric micelles [15], and surface coatings [16]. On the other hand, both agencies issued documents on the development of follow-on versions of NBCD products such as EMA documents on iron-based nano-colloidal products [17–19] and on existing products [20], and FDA on iron complexes [21], ciclosporin emulsions [22] and on liposome follow-on products [23–24]. Interestingly, FDA has awarded funding to characterize and clinically compare originator and follow-on versions after approving these products [25–26]. It is clear that the present arsenal of regulatory documents from these agencies will be expanded in the years to come. Hopefully, it is not too late to reach global agreement through the World Health Organization (WHO) or perhaps the International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH) initiatives. On the pharmacopoeial side, interest is growing in dealing with NBCD families. For example, a European Directorate for the Quality of Medicines and HealthCare (EDQM) working group is developing a monograph on ‘iron sucrose concentrated solution’ as an example for non-biological complexes and the United States Pharmacopeia (USP) is currently evaluating similar actions [27]. The British Pharmacopoeia (BP) has published a new monograph on iron sucrose injections, which is basically in line with the USP existing monograph.
One interesting feature of the European legal landscape is that certain NBCD product families are not approved through the centralized procedure (EMA). Instead, approval follows either the purely national procedures or the mutual recognition procedure under the aegis of national competent authorities. This is true for iron sucrose products and for oral bioactive polymer phosphate binders [28]. Considering the complexity of these products and the problems encountered in certain countries with generic versions of NBCD products (see below), approval thro ugh the centralized procedure and the CHMP team would be preferred.
For all NBCD product families where follow-on versions are on the market, a growing number of studies have become available in the public domain demonstrating examples of follow-on products that were approved by (national) competent authorities that differed structurally and/or in clinical practice from the originator products [9]. Often these differences were clinically relevant. Examples include publications by Rottembourg et al. [29]; Martin-Malo et al. [30]; Stein et al. [31]; Lee et al. [32] and Agüera et al. [33] for iron sucrose similars; and Weinstein et al. [34] and Towfic et al. [35] for glatiramer acetate follow-on products. These (clinical) examples raise questions to the regulatory science community in the countries mentioned in these publications about how appropriate the current systems are in ensuring equivalence in NBCD product quality, efficacy and safety. Is the current approach rigorous enough?
These examples provide lessons that should be communicated throughout the scientific community as well as to medical/pharmaceutical practitioners. More over, in the years to come, study of these examples can also help competent authorities to establish appropriate, science-based approval procedures for these complex drug products.
Expanding: The number of NBCD product families will continue to grow. It is time to pay attention to these (new) families and discuss their specific characteristics and their implications for the regulatory process at an early stage. Much information is often already available but there is a need to go through the archives and analyse these data so that scientific deficiencies are brought to the forefront.
Outstanding issues: for a list of outstanding issues concerning NBCD products one can refer to the list drawn up for biologicals. For example, labelling, comparability and attribute drift, NBCD-questionables (cf. bio-questionables [36]), extrapolation [37], interchangeability, substitution, and last but not least: a single global approach (WHO in the lead?) [38].
Facts please: For a fact-based debate on NBCD products we need to stimulate publications in the public domain. This will strengthen the science base for decisionmaking. Transparency of the regulatory process is another essential element for such a discussion. We hope that all parties (academic, industry and regulatory) involved in this debate will continue, and even step up their efforts to provide this science base.
Goal: We feel that the GaBI Journal and the GaBI Online platform offer excellent opportunities to stimulate awareness around the critical issues related to both new, innovative NBCD products and the introduction of follow-on versions. The growing science base for NBCD product legislation, e.g. in Europe and the US, and hopefully in other countries in the future, needs a non-biased publication outlet. With the GaBI publication platform we have the ambition to become the central and preferred publication hotspot for this complex topic.
Jon SB de Vlieger, PhD
Dutch Top Institute Pharma, PO Box 142, NL-2300 AC Leiden, The Netherlands
Professor Stefan Mühlebach, PhD
Vifor Pharma Ltd, 61 Flughofstrasse, PO Box, CH-8152 Glattbrugg, Switzerland; Department of Pharmaceutical Sciences, Pharmacenter, University of Basel, 50 Klingelbergstrasse, CH-4056 Basel, Switzerland
Vinod P Shah, PhD
NBCD Steering Committee member, Pharmaceutical Consultant, 11309 Dunleith Place, North Potomac, MD 20878, USA
Scott E McNeil, PhD
Director, Nanotechnology Characterization Laboratory, Frederick National Laboratory for Cancer Research, Leidos Biomedical Research Inc, PO Box B, Frederick, MD 21702-1201, USA
Professor Gerrit Borchard, PharmD, PhD
Professor, Biopharmaceutical Sciences, School of Pharmaceutical Sciences, University of Geneva, University of Lausanne 30, Quai Ernest-Ansermet, CH-1211 Geneva 4, Switzerland
Vera Weinstein, PhD
Teva Pharmaceutical Industries Ltd, Discovery and Product Development, Global Research and Development, Netanya, Israel
Beat Flühmann, PhD
Vifor Fresenius Medical Care Renal Pharma Ltd, 37 Rechenstrasse, PO Box, CH-9001 St Gallen, Switzerland
Sesha Neervannan, PhD
Senior Vice President, Pharmaceutical Development Brands R & D, Allergan Plc, RD2-3A, 2525 Dupont Drive, Irvine, CA 92612, USA
Emeritus Professor Daan JA Crommelin, PhD
Department of Pharmaceutical Sciences, Utrecht Institute for Pharmaceutical Sciences, Utrecht University, The Netherlands
Competing interest: All authors are members of the steering committee of the Non-Biological Complex Drug (NBCD) Working Group, hosted at the Dutch Top Institute Pharma (TI Pharma), Leiden, The Netherlands (http://www.tipharma.com/NBCD).
Provenance and peer review: Not commissioned; externally peer reviewed.
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8. Schellekens H, et al. How to regulate non-biological complex drugs (NBCD) and their follow-on versions: points to consider. AAPS J. 2014;16(1):15-21.
9. Crommelin DJA, de Vlieger, JSB. Non-biological complex drugs. The science and the regulatory landscape. Advances in the Pharmaceutical Sciences series. NY: AAPS/Springer; 2015.
10. Mühlebach S, Borchard G, Yildiz S. Regulatory challenges and approaches to characterize nanomedicines and their follow-on similars. Nanomedicine (Lond) 2015; 10(4):659-74.
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15. European Medicines Agency. Committee for Medicinal Products for Human Use (CHMP). Joint MHLW/EMA reflection paper on the development of block copolymer micelle medicinal products. 17 January 2013 [homepage on the Internet]. 2013 Jan 23 [cited 2015 Oct 15]. Available from: http://www.ema.europa.eu/docs/en_GB/document_library/Scientific_guideline/2013/02/WC500138390.pdf
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29. Rottembourg J, Kadri A, Leonard E, Dansaert A, Lafuma A. Do two intravenous iron sucrose preparations have the same efficacy? Nephrol Dial Transplant. 2011;26(10):3262-7.
30. Martin-Malo A, Merino A, Carracedo J, et al. Effects of intravenous iron on mononuclear cells during the haemodialysis session. Nephrol Dial Transplant. 2012;27(6):2465-71.
31. Stein J, Dignass A, Chow KU. Clinical case reports raise doubts about the therapeutic equivalence of an iron sucrose similar preparation compared with iron sucrose originator. Curr Med Res Opin. 2012;28(2):241-3.
32. Lee ES, Park BR, Kim JS, Choi GY, Lee JJ, Lee IS. Comparison of adverse event profile of intravenous iron sucrose and iron sucrose similar in postpartum and gynecologic operative patients. Curr Med Res Opin. 2013;29(2):141-7.
33. Agüera ML, et al. Efficiency of original versus generic intravenous iron formulations in patients on haemodialysis. Plos One. 2015;10(8):e0135967.
34. Weinstein V, Nicholas JM, Schwartz R, Grossman I, Zeskind B. Glatiramoids. In: Crommelin DJA, de Vlieger J, editors. Non-biological complex drugs. Advances in the pharmaceutical sciences series. NY: AAPS/Springer; 2015: p. 107-49.
35. Towfic F, et al. Comparing the biological impact of glatiramer acetate with the biological impact of a generic. PLoS One. 2014;9(1): e83757.
36. Halim LA, et al. How bio-questionable are the different recombinant human erythropoietin copy products in Thailand? Pharm Res. 2014;31(5):1210-18.
37. Weise M, Kurki P, Wolff-Holz E, Bielsky MC, Schneider CK. Biosimilars: the science of extrapolation. Blood. 2014;124(22):3191-6.
38. Crommelin DJA, et al. The similarity question for biologicals and non-biological complex drugs. Eur J Pharm Sci. 2015;76:10-7.
Author for correspondence: Jon SB de Vlieger, PhD; Dutch Top Institute Pharma, PO Box 142, NL-2300 AC Leiden, The Netherlands |
Disclosure of Conflict of Interest Statement is available upon request.
Copyright © 2015 Pro Pharma Communications International
Permission granted to reproduce for personal and non-commercial use only. All other reproduction, copy or reprinting of all or part of any ‘Content’ found on this website is strictly prohibited without the prior consent of the publisher. Contact the publisher to obtain permission before redistributing.
Source URL: https://gabi-journal.net/non-biological-complex-drugs-nbcds-and-their-follow-on-versions-time-for-an-editorial-section.html
Author byline as per print journal: Professor Stefan Mühlebach, PhD, Professor Arnold Vulto, PharmD, PhD, Jon SB de Vlieger, PhD, Vera Weinstein, PhD, Beat Flühmann, PhD, Vinod P Shah, PhD
Introduction: Besides biologicals, a new class of complex drugs – non-biological complex drugs (NBCDs), e.g. liposomes, iron carbohydrate products and glatiramoids – has emerged. Originator NBCD products have been approved by established regulatory rules. However, their follow-on products comprise a challenge to the regulators, manufacturers, physicians and pharmacists. |
Submitted: 12 August 2013; Revised: 24 September 2013; Accepted: 27 September 2013; Published online first: 11 October 2013
The progress in pharmaceutical sciences and manufacturing techniques together with more targeted and better-tolerated pharmaceutical formulations gave rise to a new class of medicinal products with complex macromolecular (nanoparticulate) structures, the so-called non-biological complex drugs (NBCDs) [1, 2]. Amongst others, NBCDs comprise liposomes, iron carbohydrate products and glatiramoids. The complexity of these synthetic NBCDs may even exceed that of biologicals. Originator NBCDs have received regulatory approval based on proven quality, efficacy and safety and have been established for many years. Some NBCDs have already been introduced before the growing awareness about the specific issues related to the production and characterization of nanostructures. Accordingly, regulatory approval of NBCD follow-on products is subject to a lively discussion about the requirements to prove therapeutic equivalence and being eligible as substitute for the reference product.
The Non-Biological Complex Drugs Working Group at Dutch Top Institute Pharma, a public–private partnership in The Netherlands, is a network of scientific and clinical experts from academia, industry, regulatory bodies, and knowledge institutes to discuss specific aspects of the development and evaluation of NBCDs and give its expert opinion. This paper briefly summarizes the key discussion points of a closed workshop at the FIP (International Pharmaceutical Federation) Centennial Congress in 2012, organized by the FIP Board of Pharmaceutical Sciences, in order to assist the understanding of the regulatory challenges associated with NBCD follow-on products such as the definition of science-based policies for interchange and substitution. The closed workshop on invitation only was followed by an open discussion symposium the following day at the FIP Centennial Congress about the proposed terminology and a planned paper on points to consider for regulation [3, 4].
NBCD are defined as a medicinal product of non-biological origin with an active substance that is not a homo-molecular structure, but consists of different closely related and mostly nanoparticulate structures. Accordingly, there is not a single substance that can be isolated, quantitated and fully characterized or described by state-of-the-art physicochemical analytical means [4]. Changes in the composition and morphology of an NBCD can substantially influence the quality, biological properties and therapeutic profile of the medicinal product and result from minute variations in the manufacturing process [1, 2, 5]. However, not all structural changes and mechanisms that affect the therapeutic profile are fully understood. Notably, the complexity of NBCD prevents establishing full proof of pharmaceutical equivalence by state-of-the-art analytical means, which comprises one of the two pillars in the evaluation of a generic medicinal product, see Figure 1.
In contrast to the mainly direct and systemic drug-target interaction of small molecules with defined receptors in a concentration-dependent manner, most NBCDs comprise nanoparticles from which the active ingredient has to be released or formed and then transported to certain biological compartments where the intended activity should be performed. Even a slightly different release or formation rate of the active ingredient, e.g. due to differences in higher order structure of the precursor molecules, can negatively affect the safety and efficacy profile of an NBCD or its follow-on product. For example, in products for intravenous iron therapy such as iron carbohydrate nanoparticles, the highly reactive iron is bound in a polynuclear core, which in turn is stabilized by a carbohydrate shell. After intravenous administration, this complex is first phagocytized by monocytes where the iron is released and transiently stored before it is bound to transferrin and transported to the target tissue where it exerts its action, e.g. incorporation into newly synthesized erythrocytes in the bone marrow; or is stored in an accessible compartment for later physiological use [6, 7]. Hence, the biological activity of an NBCD is not necessarily correlated to its serum pharmacokinetics (central compartment), the generics pathway’s second pillar to show bioequivalence.
In the case of glatiramoids, products that comprise a complex mixture of polypeptides for the treatment of relapsing-remitting multiple sclerosis, even no pharmacokinetic profile and no validated biomarker for efficacy are available. However, although the originator, Copaxone®, and a follow-on product are similar in many physiochemical properties, e.g. size distribution, molar ratio of amino acids; sensitive chemical and biological analyses demonstrated differences between those products, e.g. gene expression patterns of glatiramoid-primed murine splenocytes [8].
In contrast to follow-on compounds of biologicals that are evaluated according to distinct biosimilar guidelines (originally established in the EU), some NBCD follow-on products are classified as generics although the two prerequisites for the generics approach cannot be fulfilled. As outlined above, the inability to fully characterize an NBCD prevents proof of pharmaceutical equivalence or clinically meaningful differences between a follow-on NBCD and its reference product. Moreover, bioequivalence assessment in healthy volunteers does not necessarily reflect the biological fate of and therapeutic response to an NBCD as outlined by the example of the iron sucrose complex below. Notably, this lack in proof of therapeutic equivalence and potential differences in tolerability or safety of NBCD follow-on products can easily become a concern since these products are often used as chronic treatment and in patients with already poor health states, e.g. iron carbohydrate products for haemodialysis patients, liposomal formulations of cytotoxic agents for cancer patients and glatiramoids for multiple sclerosis patients [1, 9, 10]. In such patients, even slight but clinically meaningful differences between the products may interfere with clinical success and thus the feasibility for interchange with the innovator’s product.
The potential clinical consequences of the above-mentioned differences could be illustrated by comparative clinical and non-clinical studies of a well-established NBCD (iron sucrose, Venofer®) and different follow-on preparations (iron sucrose similars, ISS). One study evaluated the effects of switching iron treatment from the iron sucrose originator to an ISS in 75 consecutive stable, haemodialysis-dependent chronic kidney disease patients who underwent at least 60 dialysis sessions before and after the switch at a French dialysis centre [11]. After the switch to an ISS, haemoglobin levels decreased rapidly and anaemia medication had to be increased to return to targeted haemoglobin levels after quite a lengthy re-adjustment period. In addition to this apparent lack of therapeutic equivalence of an ISS, other ISS were associated with an increased risk of adverse events (658 patients at a South Korean centre who had been treated with the iron sucrose originator or an ISS) [12], even if the originator iron sucrose has been well tolerated before (three case reports in Germany) [13]. Furthermore, non-clinical studies showed not only differences between ISS and the originator product [14] but also among different ISS [15], particularly with respect to off-target iron disposition from ISS and induction of oxidative stress and inflammation.
In many countries generics approval of follow-on products allows automatic substitution at the pharmacy level. Since the International Nonproprietary Names of the innovator’s and follow-on products are the same, clinicians, caregivers and patients are often not aware of the change in medication. In contrast to the substitutability and interchangeability of fully characterized small molecule generics with well-established therapeutic equivalence, approval for substitution or interchange of NBCD products should only be granted on the basis of appropriate non-clinical and/or clinical comparisons. Together with the comparability of physicochemical quality this would allow to exclude clinically meaningful differences between the NBCD follow-on products and the reference product [1, 2]. Lacking information in case of insufficient response or intolerance can lead to unnecessary diagnostic tests and use of potentially more invasive and more expensive treatment options [8, 10]. Overall, drug product replacement that is guided by acquisition cost only may increase other costs and not be cost-effective from the patient’s and payer’s perspective.
At the NBCD workshop in the course of the FIP Centennial Congress 2012, experts from academia, industry, regulatory bodies and knowledge institutes agreed that there is a need for a globally harmonized approach to authorize NBCD follow-on products. This approach should be linked to an accepted common terminology [4]. Also the requirements for an abbreviated procedure showing comparability between different types of NBCD follow-on products and feasible reference products should be clear. In order to approve an NBCD follow-on product that will be interchangeable with the innovator’s product, relevant and comparative clinical and/or non-clinical trials should be performed. Aims of these studies will be an appropriate characterization of the NBCD with up-to-date analytical techniques and to identify the extent of similarity with the originator product. Clinical trials should be sufficiently powered, conducted in patients rather than healthy volunteers to cover for disease-associated changes in pharmacokinetics (PK) and pharmacodynamics (PD). Furthermore, trials should include suitable biological tests to evaluate the similarity of PK, PD and safety/tolerability in populations with similar aetiology of the disease as for the aimed indication. For these means also surrogate efficacy and safety markers may be used. Based on the degree of similarity that could be confirmed by the results of such trials and markers, approval of an NBCD follow-on product can be gradually extended to allow for interchange or even automatic substitution in newly diagnosed patients or those on existing chronic treatment. Such a stepwise similarity approach towards totality of evidence can help manufacturers of follow-on products in the development of safe and effective products and to make a realistic prediction of development costs and timelines.
Furthermore, the expert panel indicated that post-approval pharmacovigilance for NBCD and follow-on products should be based on specific brand names as already proposed earlier [16]. An information exchange among treating healthcare professionals and eventually the patient is mandatory to allow for appropriate treatment and drug product traceability in the individual patient.
An increasing number of NBCDs including nanomedicines become target for development and introduction of follow-on products. Recent clinical data with NBCD follow-on products (iron sucrose) that were approved like small molecule generics revealed significant differences in efficacy and tolerability compared to the originator product. Accordingly, regulators are prompted to establish a global regulatory framework that considers the structural complexity and specific biological properties of NBCD and provides clear guidance for the development and documentation of safe and effective follow-on products. The experts from academia, industry, regulatory bodies and knowledge institutes at the FIP 2012 workshop suggest a stepwise similarity approach that includes appropriate clinical and/or non-clinical studies that evaluate markers of PK, PD (if applicable) and safety/efficacy in relevant patient populations. As long as proof of therapeutic equivalence and similar safety profiles by appropriate studies is missing, interchange and automatic substitution between NBCDs and their follow-on products should be discouraged. Overall, a critical review of the current and emerging regulation of NBCDs and NBCD follow-on products encourage further multidisciplinary research and consensus discussions among all stakeholders to develop guidance towards the definition of an NBCD and the development of NBCD follow-on products [3].
Medical writing support was provided by Mr Walter Fürst, SFL Regulatory Affairs and Scientific Communication, Switzerland, and funded by Vifor Pharma Ltd.
Disclosure of financial and competing interests: This manuscript was written within the framework of the Non-Biological Complex Drugs Working Group, hosted at Dutch Top Institute Pharma. The NBCD Working Group is currently supported by Sanofi, Teva Pharmaceutical Industries Ltd and Vifor Pharma International Inc. Professor Stefan Mühlebach is an employee of Vifor Pharma Ltd, Dr Vera Weinstein is an employee of Teva Pharmaceutical Industries, and Dr Beat Flühmann is an employee of Vifor Fresenius Medical Care Renal Pharma.
Provenance and peer review: Not commissioned; externally peer reviewed.
Professor Stefan Mühlebach1,2, PhD
Professor Arnold Vulto3, PharmD, PhD
Jon SB de Vlieger4, PhD
Vera Weinstein1,5, PhD
Beat Flühmann1,6, PhD
Vinod P Shah1, PhD
1Steering Committee member, NBCD Working Group, TI Pharma, Leiden, The Netherlands
2Vifor Pharma Ltd, Glattbrugg, Switzerland
3Erasmus University Medical Center, Hospital Pharmacy, Rotterdam, The Netherlands
4TI Pharma, PO Box 142, NL-2300 AC Leiden, The Netherlands
5Teva Pharmaceutical Industries, Petach Tikva, Israel
6Vifor Fresenius Medical Care Renal Pharma, St Gallen, Switzerland
References
1. Borchard G, Fluhmann B, Muhlebach S. Nanoparticle iron medicinal products—requirements for approval of intended copies of non-biological complex drugs (NBCD) and the importance of clinical comparative studies. Regul Toxicol Pharmacol. 2012;64(2):324-8.
2. Schellekens H, Klinger E, Mühlebach S, et al. The therapeutic equivalence of complex drugs. Regul Toxicol Pharmacol. 2011;59(1):176-83.
3. Schellekens H, Stegemann S, Weinstein V, et al. How to regulate nonbiological complex drugs (NBCD) and their follow-on versions: points to consider. AAPS J. 2013 Sep 25. doi:10.1208/s12248-013-9533-z
4. Crommelin DJ, de Vlieger JS, Weinstein V, et al. Different pharmaceutical products need similar terminology. AAPS J. 2013 Sep 25. doi:10.1208/s12248-013-9532-0
5. Ehmann F, Sakai-Kato K, Duncan R, et al. Next-generation nanomedicines and nanosimilars: EU regulators’ initiatives relating to the development and evaluation of nanomedicines. Nanomedicine (Lond). 2013;8(5):849-56.
6. Evstatiev R, Gasche C. Iron sensing and signalling. Gut. 2012;61(6):933-52.
7. Geisser P, Burckhardt S. The pharmacokinetics and pharmacodynamics of iron preparations. Pharmaceutics. 2011;3(1):12-33.
8. Bakshi S, Chalifa-Caspi V, Plaschkes I, et al. Gene expression analysis reveals functional pathways of glatiramer acetate activation. Expert Opin Ther Targets. 2013;17(4):351-62.
9. Mamidi RN, Weng S, Stellar S, et al. Pharmacokinetics, efficacy and toxicity of different pegylated liposomal doxorubicin formulations in preclinical models: is a conventional bioequivalence approach sufficient to ensure therapeutic equivalence of pegylated liposomal doxorubicin products? Cancer Chemother Pharmacol. 2010;66(6):1173-84.
10. Varkony H, Weinstein V, Klinger E, et al. The glatiramoid class of immunomodulator drugs. Expert Opin Pharmacother. 2009;10(4):657-68.
11. Rottembourg J, Kadri A, Leonard E, et al. Do two intravenous iron sucrose preparations have the same efficacy? Nephrol Dial Transplant. 2011;26(10):3262-7.
12. Lee ES, Park BR, Kim JS, et al. Comparison of adverse event profile of intravenous iron sucrose and iron sucrose similar in postpartum and gynecologic operative patients. Curr Med Res Opin. 2013;29(2):141-7.
13. Stein J, Dignass A, Chow KU. Clinical case reports raise doubts about the therapeutic equivalence of an iron sucrose similar preparation compared with iron sucrose originator. Curr Med Res Opin. 2012;28(2):241-3.
14. Toblli JE, Cao G, Oliveri L, et al. Comparison of oxidative stress and inflammation induced by different intravenous iron sucrose similar preparations in a rat model. Inflamm Allergy Drug Targets. 2012;11(1):66-78.
15. Toblli JE, Cao G, Giani J, et al. Different effects of European iron sucrose similar preparations and originator iron sucrose on nitrosative stress, apoptosis, oxidative stress, biochemical and inflammatory markers in rats. NDT Plus 2011;4 [abstract]:SuO028.
16. Wysowski DK, Swartz L, Borders-Hemphill BV, et al. Use of parenteral iron products and serious anaphylactic-type reactions. Am J Hematol. 2010;85(9):650-4.
Author for correspondence: Professor Stefan Mühlebach, PhD, Vifor Pharma Ltd, CH-8152 Glattbrugg, Switzerland |
Disclosure of Conflict of Interest Statement is available upon request.
Copyright © 2013 Pro Pharma Communications International
Permission granted to reproduce for personal and non-commercial use only. All other reproduction, copy or reprinting of all or part of any ‘Content’ found on this website is strictly prohibited without the prior consent of the publisher. Contact the publisher to obtain permission before redistributing.
Source URL: https://gabi-journal.net/the-authorization-of-non-biological-complex-drugs-nbcds-follow-on-versions-specific-regulatory-and-interchangeability-rules-ahead.html
Author byline as per print journal: Jon SB de Vlieger1, PhD; Professor Daan JA Crommelin2, PhD; Beat Flühmann3, PhD; Professor Imre Klebovich4, PharmD, PhD, DSc; Professor Stefan Mühlebach3,5, PhD; Vinod P Shah6, PhD
Abstract: |
Submitted: 28 August 2019; Revised: 9 September 2019; Accepted: 10 September 2019; Published online first: 23 September 2019
The 3rd International Symposium on Scientific and Regulatory Advances in Biological and Non-Biological Complex Drugs: A to Z in Bioequivalence was organized in Budapest, Hungary on 12–14 November 2018 by the Department of Pharmaceutics of Semmelweis University with other Hungarian science organizations under the auspices of the International Pharmaceutical Federation (FIP), European Federation of Pharmaceutical Sciences (EUFEPS) and the NBCD Working Group hosted by Lygature [1]. The aim of the conference was to provide an update on the progress in the field by experts and to discuss recent developments in the regulatory status of nanomedicinal drug products in moderated panels with stakeholders. A widespread international group of experts from originator and generic drug companies, regulatory authorities, academia and contract research organizations participated in the meeting and discussion sessions. The conference introduced and discussed in detail the US Government Accountability Organization (GAO) report [2] on non-biological complex drugs (NBCDs) together with the US Food and Drug Administration (FDA) draft guidance on drug products containing nanomaterials [3] and the possibility of global harmonization of regulatory policies regarding NBCD products. This report highlights the main conclusions of the meeting and lists a number of topics that would benefit from further debate within the scientific and regulatory community.
The meeting was structured to discuss the following key questions:
– What is equivalence and why does it need our attention?
– Will recent technology developments solve the challenges in determining Critical Quality Attributes (CQAs) of complex drug products?
– Can the successful biosimilar development approach inspire the development of nanosimilars?
– Is there a possibility for global harmonization of regulatory policies for NBCD products and other complex drug products?
In the sections below, we summarize the discussions held during the meeting, in an attempt to answer these key questions.
What is equivalence and why does it need our attention?
Generic drug manufacturers are generally seeking therapeutic equivalence (TE) designation for their drug, as this is a prerequisite for substitution and/or interchangeability with the reference drug product (Orange Book in the US [4). Therapeutic equivalence means that the product is pharmaceutically equivalent (PE) and bioequivalent (BE) to the brand-name product, i.e. PE + BE = TE. Drug products are considered pharmaceutically equivalent if they contain the same active ingredient(s) in the same dosage form, are taken via the same route of administration and are identical in dose. Bioequivalence can be demonstrated using pharmacokinetic, or pharmacodynamic approaches, comparative clinical trials or an in vitro bioequivalence method. Already for decades, these approaches are successfully applied to small molecule drug products for drug approval. Because of the complexity of biological and NBCD products, developers encounter challenges in applying the TE concept.
For follow-on versions of biological products (biosimilars), extensive comparative characterization and preclinical studies are required followed by a limited set of clinical studies to demonstrate safety and efficacy. This may demonstrate similarity but not ‘automatically’ therapeutic equivalence. This biosimilar approach has been introduced and regularly evaluated and updated by the European Medicines Agency (EMA) and is currently considered an established, science-based regulatory approach. FDA has introduced its biosimilar approach as well, which essentially follows the EMA principles.
Determination of TE, through PE and BE, of NBCD products, including nanomedicines, can be a significant challenge. The first discussion on this issue in Budapest in 2014 identified the problem and indicated that CQAs are key to determine TE [5]. The preferred regulatory pathways to establish TE for NBCDs was debated during a number of meetings, including at the New York Academy of Sciences in 2016 [6] and subsequently at the second conference in Budapest in 2016 [7]. Because of the difficulties involved in assessing equivalence with the originator NBCD products, concerns have been raised about safety and efficacy that might appear only after the follow-on versions are introduced on the market.
During the discussions, the topic of consistent terminology has also been raised. Earlier in 2014, a terminology paper was released by the NBCD Working Group [8]. Since then, several new items popped up and the most recent discussion on terminology has evolved around using the terms ‘generic’, ‘follow-on’ and ‘similar’. In a recent publication, Marden et al. make an important statement that terminology in the regulatory field should be used correctly and consistently [9]. As the word ‘generic’ implies therapeutic equivalence and substitutability, this report refers to follow-on products and similars for complex drug products that cannot be fully characterized by physicochemical characterization. The term complex generic is mainly used by FDA and EMA tends to use follow-on, and/or similar.
Will recent technology developments solve the challenges in determining Critical Quality Attributes of complex drug products?
Identification and a thorough (physicochemical) characterization of CQAs is an important step towards the development of a follow-on or similar complex drug product. According to ICH ‘a CQA is a physical, chemical, biological, or microbiological property or characteristic that should be within an appropriate limit, range, or distribution to ensure the desired product quality’. In other words, a critical attribute is a property of which its variation will adversely impact the quality and the clinical profile of the product. At present, both EMA and FDA have adopted a stepwise approach in similarity determination of biosimilars. The development of a biosimilar product therefore requires a thorough comparative in vitro (physico-)chemical characterization of (critical) quality attributes of the test product with the reference product. These thorough analytical comparability studies are followed by non-clinical and clinical studies.
Acknowledging the present challenges to assess CQAs for NBCD products and their design space (DS) that would lead to PE, attention should be paid to further research on elucidating mechanisms of action and on the development and validation of relevant analytical techniques.
This is broadly recognized as, in the meeting, recent developments in state-of-the-art technologies were presented. More importantly, examples were presented how these technologies were applied in the process of characterizing complex drug products. Although the relevance of application of such advanced technologies is to be seen on a product-by-product basis, the progress in technology development for sure impacts the efficiency of characterization activities and brings CQA/DS information closer by.
Can the successful biosimilar development approach inspire the development of nanosimilars?
In a report on an earlier meeting in the SRACD Conference series, the similarities between the complexity of biological and non-biological complex drug products and the implications for TE assessment [5] were pointed out. These discussions continued and the idea of applying the biosimilar paradigm to other complex drug products gained traction. Very concretely, following a publication by authors from EMA, a nanosimilar evaluation process was suggested using the ‘totality of evidence’ concept with a stepwise procedure [10]. This stepwise procedure includes physicochemical structural characterization, animal toxicity studies, in vivo comparative equivalence studies (PK/PD).
For example, in a series of reflection papers for intravenous iron-based nano-colloidal products EMA (proposes a stepwise procedure and ‘totality of evidence’ approach [11].
The success of a new drug modality concept is depending on more factors than appropriate regulatory frameworks alone. In the end, the adoption of new technology and its related products needs multi-stakeholder support. A major effort by different stakeholders was made to explain the scientific background of the biosimilar concept and clinical experience with these biosimilars to healthcare professionals [12]. The EMA brochure on biosimilars from 2017 is a good example of such an effort [13]. Stakeholders in the nanomedicine field should use this successful example of a policy to inform healthcare professionals about the specific challenges encountered with nanosimilars, now and in the future. A first step has already been made by Astier et al. by publishing a list of factors to consider when selecting a nanosimilar [14].
Is there a possibility for global harmonization of regulatory policies for NBCD products and other complex drug products?
The success of harmonization efforts can be judged when comparing the content of guidance documents and reflection papers by the regulatory authorities. A prominent example of guidance documents that could be harmonized are those concerning the approval of follow-on doxorubicin liposome formulations.
Liposomes are one of the most important classes of NBCD products that are used since years in patients. The complexities of liposomal drug products are recognized and dealt with in the FDA and EMA guidance reflection documents. Major efforts were undertaken through the Global Bioequivalence Harmonization Initiative, with participation of EMA and FDA, to align the approaches by the two regulators. It is important to differentiate between nice-to-know and need-to-know requirements. At present, and despite the harmonization exercise, FDA and EMA have taken different decisions on essentially the same follow-on formulation of Doxil®. Moreover, very recently, a case study was published describing the authorization of a generic version Copaxone® in Europe and the US. Whilst EMA requested a full clinical assessment programme, US FDA approved a follow-on version of Copaxone without any clinical data supporting therapeutic equivalence. The approval of these follow-on versions evaluated through different approaches by both agencies leaves open questions on the equivalence of these drug products [15].
In response to concerns raised by the scientific community, the US Government Accountability Office (GAO) was asked to assess FDA’s process of reviewing follow-on versions of NBCD products. In the conclusion and recommendations section, the GAO report underlined the scientific challenges involved when demonstrating equivalence between brand and generic NBCD products [2]. One of the main conclusions was that although all stakeholders agreed that demonstration of equivalence of follow-on NBCDs is scientifically challenging, no agreement could be found on how to move forward and whether the current legislation is sufficient. See Table 1 for a list of conclusions distilled from the full report.
Of note, shortly after the release of the GAO report, FDA issued a draft guidance for industry in December 2017 on ‘Drug products including biological products that contain nanomaterials’ [3]. The agency identified 11 key factors for the assessment of drug products containing nanomaterials. To discuss this draft guidance, an AAPS Guidance Forum workshop was held in September 2018 in Washington DC and the report of that workshop was published earlier in 2019 [16].
In Europe, the debate on whether similar versions of NBCD products should follow the centralized approval procedure are ongoing. A recent approval of an iron carbohydrate similar through the hybrid 10(3) pathway instead of earlier 10(1) generic drug approvals indicates that the field is moving. An overview of all NBCD products and their follow-on versions approved in Europe was recently published by Klein et al., presenting an interesting view on how these products were approved over the years and where the regulatory system may be improved [17].
Just before resigning from office, the former FDA Commissioner Scott Gottlieb voiced his opinion in support of an ICH approach in the area of complex generic drug products [18]. It is to be seen how this will develop, but the scientific and regulatory community should be ready to engage in discussions to increase coherence in the regulatory approach for this type of products.
The meeting successfully brought together experts from all relevant stakeholders, including regulatory authorities, academic institutes, generic and innovative pharmaceutical companies. Participants came from all over the world (five continents, 44 countries) and actively participated in the debates. It is important to note that compared to previous SRACD meetings, significant progress was made in formulating answers to the above four questions. Progress may have been made, but there was also a clear call for action to take the international discussions around alignment and harmonization to the next level.
This paper may include opinions of the authors and not necessarily the opinions of their employers. Authors JdV, DC, BF, IK, SM, VS are members of the Non-biological Complex Drugs Working Group, hosted at Lygature, The Netherlands (www.lygature.org/NBCD).
The authors declare that there is no funding received to prepare this manuscript.
Competing interests: BF and SM are employees of Vifor Pharma Ltd, Glattbrugg, Switzerland.
Provenance and peer review: Not commissioned; externally peer reviewed.
1Foundation Lygature, 6 Jaarbeursplein, NL-3521 AL Utrecht, The Netherlands
2Department of Pharmaceutics, Utrecht University, Utrecht, The Netherlands
3Vifor Pharma Ltd, Glattbrugg, Switzerland
4Semmelweis University, Department of Pharmaceutics, Budapest, Hungary
5Department Pharmaceutical Sciences, Unit of Clinical Pharmacy and Epidemiology, University of Basel, Basel, Switzerland
6VPS Consulting LLC, North Potomac, MD, USA
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9. Marden E, Ntai I, Bass S, Flühmann B. Reflections on FDA draft guidance for products containing nanomaterials: is the abbreviated new drug application (ANDA) a suitable pathway for nanomedicines? AAPS J. 2018;20(5):92.
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11. European Medicines Agency. Reflection paper on the data requirements for intravenous iron-based nano-colloidal products developed with reference to an innovator medicinal product. 26 March 2015 [homepage on the Internet]. [cited 2019 Sep 9]. Available from: https://www.ema.europa.eu/en/documents/scientific-guideline/reflection-paper-data-requirements-intravenous-iron-based-nano-colloidal-products-developed_en.pdf
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Author for correspondence: Jon SB de Vliegr, PhD, Coordinator, NBCD Working Group, p/a Foundation Lygature, 6 Jaarbeursplein, NL-3521 AL Utrecht, The Netherlands |
Disclosure of Conflict of Interest Statement is available upon request.
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