Abstract
Access policies of biobanks specify the governance of sample and data sharing. Basic guidance on relevant access criteria exists, but so far little is known about their public availability and what criteria for access and prioritization they actually include. Access policies were gathered by hand searching the websites of biobanks identified via registries (eg, BBMRI and P3G), and by additional search strategies. Criteria for access and prioritization were synthesized by thematic analysis. Of 523 biobank websites screened, 9% included a publicly available access policy. With all applied search strategies, we finally retrieved 74 access policies. Thematic analysis resulted in 62 different access criteria in three main categories: (a) scientific quality, (b) value and (c) ethical soundness. ‘Scientific quality’ criteria were mentioned in 70% of all policies, ‘value’ criteria in 33% and ‘ethical soundness’ criteria in 73%. Criteria for prioritization were specified in 27% of all policies. Access policies differed broadly in number, specification and operationalization of the included access criteria. In order to make biobank research more effective, efficient and trustworthy, access policies should be more available to the public. Furthermore, access policies should aim for precise and more harmonized wording of access criteria. From a public and governance perspective, the issue of how to prioritize access to scarce samples should form part of access policies.
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Introduction
Human biobanks collect, process, store and distribute human biological samples and associated data. Biobanks are widely recognized as valuable resources for biomedical research, as access to samples and their related data is essential to basic, translational, clinical, epidemiological and diagnostic research. Owing to their growing importance, the number of biobanks has considerably increased worldwide. For instance, the first catalog issued by the pan-European Biobanking and Biomolecular Resources Research Infrastructure (BBMRI) comprised >300 biobanks in 2011. The new BBMRI-ERIC directory, released in 2015, already comprises >500 biobanks. A recent study identified over 600 biobanks in the United States.1 Notably, public money has been used to establish and build up many of these biobanks.2 In Germany, for instance, the Federal Ministry of Education and Research (BMBF) allocated about 18 million euros over 5 years from 2011 to fund a national biobank initiative. A second funding round is currently underway.3 A central aim of such national funding initiatives is to ready local and national biobanks for international cooperation and networking.
As the overall and long-term value of research biobanks rests on the collected samples and data, there is an obvious need for good governance of access to these collections. Accordingly, the issues of sample and data ownership, access to samples and data sharing have been well debated internationally.4, 5, 6, 7, 8, 9, 10, 11
A core challenge with regard to the governance of access is that stakeholders in biobank research have different and sometimes conflicting interests and responsibilities. First, biobanks invest financial and human resources to build the infrastructure for the acquisition, processing, and storage of samples and data. Biobanks therefore seek academic or monetary recognition of their efforts (‘compensation’) when material or data are used in individual research projects. Second, individual researchers and their affiliations (academic/clinical departments) who contribute to the development of a specific biobank legitimately pursue their own interests (eg, career, international reputation via improved local research conditions). Third, if biobanks are publicly funded, the funders may oblige biobanks to allow uses of samples and data with high scientific and social value (another sort of ‘compensation’).8 Fourth, sample donors bear burdens and risks when participating in biobank research; often small, but non-negligible. These mostly comprise potential breaches of confidentiality (eg, re-identification of anonymized or pseudonymized data),12 and in some cases burdens or risks involved in sample donation (eg, risks of bleedings, local infections and expenditure of time). Risks and burdens borne by sample donors are another (reciprocity-based) reason for biobanks to pursue research of high scientific and social value.7
How do these four interests relate to biobanks’ access policies? There is a greater likelihood of high scientific and social value (in the interest of sample donors and public funders) when samples and data are also available to external researchers. Researchers are ‘external’ if they are not affiliated with the biobank and/or have not contributed to the specific sample collection they are interested in. However, they might have very promising, sound research questions.13 Further, some research questions might require large numbers of samples, access to which would be facilitated by international networking. These broader academic and public interests in high value biobank research might conflict with interest of biobank staff and local researchers aiming for prioritized access to local samples, or other benefits, in return for their efforts. This conflict demonstrates the need for reasonable and practice-oriented governance of access to samples and data.
To address public, scientific and local needs sustainably, sound criteria and procedures are crucial. In its 2012 Best Practices, the International Society for Biological and Environmental Repositories (ISBER) addresses this point by calling for the establishment of biobank-specific access policies, describing them as a key mechanism for access governance.14 Basic guidance on the formulation of access policies already exists, and highlights the need for concise evaluation criteria for access decisions.8, 9, 15, 16
A recent study by Verlinden et al17 has already revealed interesting features of access policies’ formal aspects. The study identifies 21 key conditions, which relate to access to samples or data, such as ownership, custodianship and data protection issues. However, little is known still about the precise criteria individual biobanks apply when researchers request access to samples and data.
Moreover, how biobanks prioritize access to scarce but highly requested samples has not been assessed at all. The issues of priority setting and fair allocation of scarce samples are not new, either. ISBER, for example, says that access to samples should be prioritized when necessary, for example, in cases where demand outstrips supply. Unlike data, biomaterials can be used up. A sample of cancer tissue, for example, cannot be used in an unlimited number of research projects, because within the course of research the sample or at least certain quantities of the sample will be destroyed. Therefore, decisions about access to ‘scarce’ biomaterials unavoidably become priority-setting decisions.
To enable evidence-based discussion around the current state and potential revisions of access policies in biobank research, this study aimed to chart the public availability of access policies in a cross-sectional study. In this regard, public availability is defined as the possibility to receive the required information easily by consulting the biobank's specific website. The study further aimed to assess the full qualitative spectrum of access and prioritization criteria currently used in access policies.
Methods
Search for access policies
First, we contacted all biobanks listed in the BBMRI catalog18 (N=333, as of June 2015) via e-mail and asked for documents describing each biobank’s access policy. In our contact e-mail, we explicitly outlined the scientific aims of our study, that all policies would be kept confidential, and that we would not report biobank names in our results. However, owing to the low response rate of n=14 (4%), we needed additional search strategies.
Our second strategy was to check biobank websites to identify either downloadable documents or otherwise published information on how access is regulated. This second search strategy was not only used to increase the number of retrieved access polices for the planned text analysis (see below) but also to determine the percentage of biobanks that have publicly available access policies. Our definition of ‘publicly available’ access policy was narrowed down to ‘available via the biobank’s website’. In this regard, we did not include other types of availability such as ‘availability on request’ (via e-mail or telephone) for the following reasons: first, any ‘on request procedure’ might give the impression that the amount of information with regard to the access regulations is depending on who is asking. Second, there can be substantial delays in getting access to access policies if this involves contacting biobank staff and waiting for their responses. Third, it simply does not cover the true meaning of ‘publicly available’ if a document is ‘hidden’ behind an ‘on request’ procedure.
We searched the websites of all biobanks listed in the catalogs from BBMRI (N=333) and the Public Population Project in Genomics (P3G) observatory (N=164). We further checked all biobank websites listed on the website of the Australasian Biospecimen Network (N=26). Finally, two additional web searches were conducted in Google with the search expression (1) ‘access policy’ AND ‘biobank’, and (2) ‘access policy’ AND ‘biorepository’. Here, the first 100 hits (sorting by relevance) were included. Finally, duplicates were removed. The search was carried out between May and August 2015.
We included every written document that described a biobank’s access regulations (eg, ‘rules for access and use’, ‘terms for use’, ‘ethics and governance framework’ etc.). We did not restrict our analysis to one specific type of biobank (eg, population banks, disease-specific biobanks).19 Only access policies in English or German were included.
Analysis and synthesis of access criteria
To extract, analyze and synthesize the relevant information on access criteria, thematic text analysis was applied to all included access policies.20 First, a subset of 12 policies was systematically analyzed by two researchers independently (HL and HK). Paragraphs that mentioned aspects related to access to samples and/or data were identified. Each paragraph considered relevant was copied in full into an Excel file and a descriptive code was applied. Second, the findings were compared with identify any differences in coding. However, only minor differences occurred, and were resolved by discussion. Coding was performed inductively and deductively. Deductive coding was based on the criteria listed in the ‘P3G Model Framework for Access Policy: Core Elements’.15 Third, criteria mentioned in each access policy were correlated, to collate the various codes and cluster the findings into an initial matrix of categories and subcategories. This matrix served as a starting point for the further thematic analysis of the remaining access policies. One researcher (HL) used the above-described approach to add and modify codes until theoretical saturation was achieved for the main categories and the first-order subcategories. Theoretical saturation implies that no new categories can be generated for the theoretical framework that forms the primary endpoint of the thematic analysis.21 This resulted in a pre-final matrix of broad and narrow categories for access criteria. Two other researchers (HK and SS) then checked all access policies and the resulting matrix and proposed changes. All researchers discussed and slightly modified the matrix for internal consistency and agreed the final matrix.
Results
Of 523 biobank websites, 48 (9%) offered a publicly available access policy. Fifteen policies (5%) were from the 333 BBMRI biobanks, 20 policies (12%) from the 164 P3G biobanks and 13 policies (50%) from the 26 biobanks linked on the Australasian Biospecimen Network website. Another 12 policies were identified via the additional Google search. Together with the 14 policies received via the initial e-mail survey of BBMRI biobanks (see Methods), we analyzed a total of 74 access policies (Table 1).
Via thematic text analysis, we identified and categorized a total of 62 access criteria in three main categories: ‘scientific quality’, ‘ethical soundness’ and ‘value’. Table 2 presents the 62 criteria under their main categories together with quantitative data for their representation in the 74 access policies (Table 2). In addition, some biobanks categorically exclude access to samples and data for specific reasons (Table 3).
Also, procedures and technical conditions for access differed widely, but we did not assess these issues systematically. An extended table illustrating the spectrum of 62 access criteria with exemplary text passages from the access policies can be found in the annex (Online Supplement). Of the 62 subcriteria, 48 were mentioned in fewer than 10 access policies, and 24 were mentioned only once.
Fifty-nine access policies (80%) refer to the main category ‘scientific quality’. At the meso level, scientific quality is further specified by ‘quality safeguards’, ‘methodological quality’ and/or ‘capacities and infrastructure’ (Table 2). Examples for ‘methodological quality’ include subcriteria such as ‘sound methodology’ and ‘sound sample size’. Examples for ‘capacities and infrastructure’ include subcriteria such as ‘relevant expertise of researchers’ and ‘sufficient resources and funding’.
‘Value’, the second main category, is addressed in 31 (42%) access policies and further divided into ‘scientific value’ and ‘health related value’ (Table 2). Examples of ‘scientific value’ include subcriteria such as ‘scientific research purposes only’ and ‘novelty and innovation’. Examples of ‘health related value’ include ‘expected impact on clinical practice’ and ‘expected impact on public health’.
The third main category, ‘ethical soundness’, is referred to in 56 (76%) access policies, and comprises two criteria, ‘adherence to ethical statutes and guidelines’ and ‘donor protection’ (Table 2). Examples of ‘adherence to ethical statutes and guidelines’ include subcriteria such as ‘independent ethical approval’ and ‘conformity with biobank statutes’. Examples of ‘donor protection’ include subcriteria such as ‘conformity with donor consent’ and ‘data protection’.
Of those criteria that specify how to make access decisions, we distinguished 14, which immediately deny access (‘a priori exclusion criteria’) (Table 3). These criteria can be either project related or researcher related. Examples of project-related exclusion criteria include ‘research for commercial purposes’ and ‘research with final aliquots’. Examples for researcher-related exclusion criteria are ‘previous non-compliance with guidelines’ and ‘local researchers only’.
Prioritization is referred to in 20 access policies (27%), and a total of 15 subcriteria were identified for the prioritization of sample allocation (Table 4). The criterion most often used for prioritized access was ‘priority for active members (contributing/collecting)’ (n=4), followed by ‘priority for network members’, ‘regional or national benefit’ and ‘indication’ (each n=3). The other 10 criteria are mentioned in only one access policy each.
Finding the biobanks’ websites was often complicated by missing or incorrect links in the respective registries (Table 5). For 74 (22%) biobanks in the BBMRI catalog and for 15 (9%) biobanks in the P3G catalog, we were not even able to find a website, either from a link in the catalog or by additional Google searches.
Discussion
This is the first study to investigate the public availability of individual biobanks’ access policies. It demonstrates that only 9% of 523 websites from biobanks provide an access policy or other relevant access information. Public availability differed across biobank networks. Although 50% of the 26 biobanks in the Australasian Biospecimen Network have publicly available access policies, only 5% of the 333 BBMRI-registered biobanks and 12% of the P3G-registered biobanks do.
This study does not represent all existing biobanks but only those identified via the websites from internationally well-known biobank networks and additional Google searches. Furthermore, the lack of publicly available access policies does not necessarily indicate that no access policy or explicit access criteria are in use. For instance, in this study, ‘conformity with donor consent’ was found in only 32% of all access policies, but we assume that many more biobanks would require this conformity. Reasons for the apparent wide-spread lack of access to access policies might be manifold (eg, administrative barriers and lack of awareness) and need further evaluation. However, this current lack of information entails other challenges, which are described in the following sections.
This study also analyzed the full text of 74 access policies, and revealed a qualitative spectrum of 62 different access criteria that can be grouped under three main criteria. We did not aim to further complement our sample of 74 access policies, because we could demonstrate theoretical saturation (an essential validity criterion in qualitative research) for our primary endpoint, namely the qualitative spectrum of access criteria. The assessed policies varied widely in terms of which criteria they included and how they were further elaborated. Criteria for priority setting, that is, criteria to guide biobanks in challenging decisions on who gets more or less prioritized access to finite samples, were specified in a minority (27%) of access policies.
The argument for better access to access policies
A large majority of biobanks are non-profit organizations. Results from a US survey indicated that only around 5% of biobanks operate on a for-profit basis.22 As outlined in the Introduction section, public funding as well as burdens and risks borne by sample donors put some (reciprocity-based) obligation on biobanks to pursue research with high scientific and social value. Against this background, some authors have argued for a ‘stewardship model’, requiring biobanks to prioritize best use and avoid underutilization of samples.23, 24, 25, 26 Thus, biobanks ought to make all necessary arrangements that facilitate the best possible utilization of the samples. A key task in this regard would be to facilitate the access to informative access policies.
The lack of publicly available access policies would not only contradict this obligation of stewardship but could also diminish public trust, willingness to donate samples and public funding. Biobanks, therefore, should have meaningful access policies and make them publicly accessible.
To improve the current status quo research infrastructrures such as BBMRI-ERIC and P3G could require access policies as a prerequisite to listing in their registries. Similarly, public funders might require (and not only recommend) publicly available access policies with at least some opportunity for external access.
An improved public accessibility of access policies might also facilitate networking with interested researchers.
More practice-oriented and context-specific normative analysis would be needed to determine how individual biobanks should balance (A) local interests in prioritized access to stored samples or other approaches to appropriate return on investment and (B) the above-mentioned interests of sample donors and public funders.
Guidelines or templates to improve quality and harmonization of access policies?
The ‘P3G Model Framework for Access Policy: Core Elements’ gives extensive advice on the format and wording of access policies, but restrict its advice to 10 access criteria, of which some are rather broad and would need to be further elaborated to be used in practice. Other available guidance on the design and formulation of access policies also fails to reflect the variety of potentially relevant access criteria.8, 9, 15, 16
Although guidelines with more fine-grained advice might improve the quality of access policies, it is questionable whether they would also support harmonization of access policies. Harmonization in biobank governance is important to international cooperation and networking in biobank research.19 To this end, a systematically derived template for access policies might be more useful than or at least complement improved guidelines. Such a template would include precise text passages for potentially relevant access criteria and allow a quick adjustment for biobank-specific characteristics, national laws or other local sensitivities. A template for harmonized consent forms in German biobank research was published recently.27 If a similar type of template will be developed for access policies it should be an evidence based and participatory effort, involving all relevant stakeholder groups in biobank research (eg, biobank researchers, biobank managers, policy makers and patient groups). The 62 access criteria presented in this study build important evidence in this regard and might function as a starting point for the template development.
Insufficient awareness of prioritization
Most of the analyzed access policies did not clearly differentiate between (A) access to materials and data and (B) prioritized allocation of scarce materials. Prioritization, however, should be regarded as following the initial access decision. For example, demanding a ‘sound methodology’, ‘relevant expertise of the researchers’ and ‘positive ethics approval’ might all be relevant criteria to the decision on access (‘yes/no’). But such binary criteria do not meaningfully inform how to prioritize access (‘more/less’) if two or more competing sample requests are made that fulfill the basic access criteria.
Even when the need for prioritization is mentioned in some access policies, not all criteria currently applied to priority setting seem equally useful. For instance, the ‘first come first serve’ approach (Table 4) is a simple and effective way to prioritize samples, but can at the same time prevent samples being used in a way that optimizes scientific and social value. Prioritization should ideally be based on criteria that allow for a ranking. But even criteria that allow rankings might be more or less justifiable. For instance, an assessment of scientific merit might be challenging for several reasons. One reason is that it requires advanced expertise and method knowledge but also expertise with regard to current developments in very specific scientific communities. Another reason is that biobank research is a dynamic field driven by technical innovations that demand a non-rigid understanding of scientific merit.
Future conceptual and normative analysis is needed to define practically feasible and normatively appropriate criteria for prioritized access to samples stored in biobanks. The presented spectrum of 62 access criteria might function as important background material to inform discussion and decision making in this regard.
Our search for access policies coincided with the release of the new directory BBMRI-ERIC (European Resources Research Infrastructure Consortium), which was launched in July 2015. The BBMRI registry used in this study was no longer updated; the new directory now comprises >500 biobanks. Thus, our finding that currently only 9% of all 523 analyzed biobank websites offer information on access policies should be reassessed in the future, together with empirical studies on potential barriers and facilitators for more transparent and meaningful access policies.
References
Boyer GJ, Whipple W, Cadigan RJ, Henderson GE : Biobanks in the United States: how to identify an undefined and rapidly evolving population. Biopreserv Biobank 2012; 10: 511–517.
Vaught J, Rogers J, Myers K et al: An NCI perspective on creating sustainable biospecimen resources. J Natl Cancer Inst Monogr 2011; 2011: 1–7.
German Federal Ministry for Education and Research: Bekanntmachung des Bundesministeriums für Bildung und Forschung der Richtlinie zur Förderung der 'Ertüchtigung deutscher Biobank-Standorte zur Anbindung an BBMRI' 2015.
Capron AM, Mauron A, Elger BS, Boggio A, Ganguli-Mitra A, Biller-Andorno N : Ethical norms and the international governance of genetic databases and biobanks: findings from an international study. Kennedy Inst Ethics J 2009; 19: 101–124.
Ness RB : Biospecimen ‘ownership’: point. Cancer Epidemiol Biomarkers Prev 2007; 16: 188–189.
Mascalzoni D, Dove ES, Rubinstein Y et al: International charter of principles for sharing bio-specimens and data. Eur J Hum Genet 2015; 23: 721–728.
Knoppers BM, Harris JR, Tasse AM et al: Towards a data sharing code of conduct for international genomic research. Genome Med 2011; 3: 46.
Fortin S, Pathmasiri S, Grintuch R, Deschenes M : 'Access arrangements' for biobanks: a fine line between facilitating and hindering collaboration. Public Health Genomics 2011; 14: 104–114.
Lemrow SM, Colditz GA, Vaught JB, Hartge P : Key elements of access policies for biorepositories associated with population science research. Cancer Epidemiol Biomarkers Prev 2007; 16: 1533–1535.
Shabani M, Dyke SO, Joly Y, Borry P : Controlled access under review: improving the governance of genomic data access. PLoS Biol 2015; 13: e1002339.
Shabani M, Knoppers BM, Borry P : From the principles of genomic data sharing to the practices of data access committees. EMBO Mol Med 2015; 7: 507–509.
Gymrek M, McGuire AL, Golan D, Halperin E, Erlich Y : Identifying personal genomes by surname inference. Science 2013; 339: 321–324.
Bobrow M : Balancing privacy with public benefit. Nature 2013; 500: 123.
International Society for Biological and Environmental Reposotories (ISBER): 2012 best practices for repositories collection, storage, retrieval, and distribution of biological materials for research international society for biological and environmental repositories. Biopreserv Biobank 2012; 10: 79–161.
P3G: P3G model framework for access policy: core elements. Public Population Project in Genomics and Society (P3G) 2013. Available at: http://www.p3g.org/system/files/biobank_toolkit_documents/P3G%20Core%20Elements%20Access%20Policy%20Final%20Dec%202013.pdf (accessed on 24 July 2015).
NCRI: Samples and data for research: template for access policy development. Natl Cancer Res Inst 2009. Available at: http://www.ncri.org.uk/wpcontent/uploads/2013/09/Initiatives-Biobanking-2-Accesstemplate.pdf (accessed on 13 July 2015).
Verlinden M, Nys H, Ectors N, Huys I : Access to biobanks: harmonization across biobank initiatives. Biopreserv Biobank 2014; 12: 415–422.
Wichmann HE, Kuhn KA, Waldenberger M et al: Comprehensive catalog of European biobanks. Nat Biotech 2011; 29: 795–797.
Riegman PH, Morente MM, Betsou F, de Blasio P, Geary P Marble Arch International Working Group on Biobanking for Biomedical R: Biobanking for better healthcare. Mol Oncol 2008; 2: 213–222.
Dixon-Woods M, Agarwal S, Jones D, Young B, Sutton A : Synthesising qualitative and quantitative evidence: a review of possible methods. J Health Serv Res Policy 2005; 10: 45–53.
Strauss AL, Corbin JM : Basics of qualitative research. Techniques and procedures for developing grounded theory, 2 edn. Thousand Oaks, CA, USA: Sage Publishing, 1998.
Henderson GE, Cadigan RJ, Edwards TP et al: Characterizing biobank organizations in the US: results from a national survey. Genome Med 2013; 5: 3.
Fullerton SM, Anderson NR, Guzauskas G, Freeman D, Fryer-Edwards K : Meeting the governance challenges of next-generation biorepository research. Sci Transl Med 2010; 2: 15cm13.
O'Brien SJ : Stewardship of human biospecimens, DNA, genotype, and clinical data in the GWAS era. Annu Rev Genomics Hum Genet 2009; 10: 193–209.
Henderson GE, Edwards TP, Cadigan RJ et al: Stewardship practices of U.S. biobanks. Sci Transl Med 2013; 5: 215cm217.
Yassin R, Lockhart N, Gonzalez del Riego M et al: Custodianship as an ethical framework for biospecimen-based research. Cancer Epidemiol Biomarkers Prev 2010; 19: 1012–1015.
Strech D, Bein S, Brumhard M et al: A template for broad consent in biobank research. Results and explanation of an evidence and consensus-based development process. Eur J Med Genet 2016, (online first) 59: 295–309.
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Conceived and designed the research study: HL and DS. Acquired the data: HL and SS. Analyzed the data: HL, HK and SS. Wrote the manuscript: HL and DS.
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Langhof, H., Kahrass, H., Sievers, S. et al. Access policies in biobank research: what criteria do they include and how publicly available are they? A cross-sectional study. Eur J Hum Genet 25, 293–300 (2017). https://doi.org/10.1038/ejhg.2016.172
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DOI: https://doi.org/10.1038/ejhg.2016.172
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