Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-22T03:33:33.426Z Has data issue: false hasContentIssue false

The ethical challenges of diversifying genomic data: A qualitative evidence synthesis

Published online by Cambridge University Press:  12 September 2023

Faranak Hardcastle*
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK Clinical Ethics, Law and Society (CELS), The NIHR Southampton Biomedical Research Centre, University of Southampton, Southampton, UK
Kate Lyle
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK Clinical Ethics, Law and Society (CELS), The NIHR Southampton Biomedical Research Centre, University of Southampton, Southampton, UK
Rachel Horton
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK
Gabrielle Samuel
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK King’s College London, London, UK
Susie Weller
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK Clinical Ethics, Law and Society (CELS), The NIHR Southampton Biomedical Research Centre, University of Southampton, Southampton, UK
Lisa Ballard
Affiliation:
Clinical Ethics, Law and Society (CELS), The NIHR Southampton Biomedical Research Centre, University of Southampton, Southampton, UK
Rachel Thompson
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK
Luiz Valerio De Paula Trindade
Affiliation:
Clinical Ethics, Law and Society (CELS), The NIHR Southampton Biomedical Research Centre, University of Southampton, Southampton, UK
José David Gómez Urrego
Affiliation:
Clinical Ethics, Law and Society (CELS), The NIHR Southampton Biomedical Research Centre, University of Southampton, Southampton, UK
Daniel Kochin
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK
Tess Johnson
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK
Nechama Tatz-Wieder
Affiliation:
Big Data Institute, University of Oxford, Oxford, UK
Elizabeth Redrup Hill
Affiliation:
PHG Foundation, University of Cambridge, Cambridge, UK
Florence Robinson Adams
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK Centre for Science and Policy, University of Cambridge, Cambridge, UK
Yoseph Eskandar
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK
Eli Harriss
Affiliation:
Bodleian Health Care Libraries, University of Oxford, Oxford, UK
Krystal S. Tsosie
Affiliation:
Arizona State University, Tempe, AZ, USA
Padraig Dixon
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK Nuffield Department of Primary Care Health Sciences, University of Oxford, Oxford, UK
Maxine Mackintosh
Affiliation:
Genomics England Ltd, London, UK Alan Turning Institute, London, UK
Lyra Nightingale
Affiliation:
Genomics England Ltd, London, UK
Anneke Lucassen
Affiliation:
Clinical Ethics, Law and Society group (CELS), and Centre for Personalised Medicine, Wellcome Centre for Human Genetics, University of Oxford, Oxford, UK Clinical Ethics, Law and Society (CELS), The NIHR Southampton Biomedical Research Centre, University of Southampton, Southampton, UK
*
Corresponding author: F. Hardcastle; Email: faranak.hardcastle@well.ox.ac.uk
Rights & Permissions [Opens in a new window]

Abstract

This article aims to explore the ethical issues arising from attempts to diversify genomic data and include individuals from underserved groups in studies exploring the relationship between genomics and health. We employed a qualitative synthesis design, combining data from three sources: 1) a rapid review of empirical articles published between 2000 and 2022 with a primary or secondary focus on diversifying genomic data, or the inclusion of underserved groups and ethical issues arising from this, 2) an expert workshop and 3) a narrative review. Using these three sources we found that ethical issues are interconnected across structural factors and research practices. Structural issues include failing to engage with the politics of knowledge production, existing inequities, and their effects on how harms and benefits of genomics are distributed. Issues related to research practices include a lack of reflexivity, exploitative dynamics and the failure to prioritise meaningful co-production. Ethical issues arise from both the structure and the practice of research, which can inhibit researcher and participant opportunities to diversify data in an ethical way. Diverse data are not ethical in and of themselves, and without being attentive to the social, historical and political contexts that shape the lives of potential participants, endeavours to diversify genomic data run the risk of worsening existing inequities. Efforts to construct more representative genomic datasets need to develop ethical approaches that are situated within wider attempts to make the enterprise of genomics more equitable.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

Impact statement

The overrepresentation of genomic data from individuals of Northern-European descent in biobanks worldwide is now a well-recognised issue. Despite global efforts to improve the representation of individuals from other ancestry groups, this skewing remains, and various populations remain underrepresented and underserved in commonly used repositories worldwide. It is crucial to address this issue as it can lead to inequities in genomic medicine, and ultimately in health inequalities. This is because research and technologies can inherit biases from use of skewed data. This article synthesises evidence from the literature on the complex historical, social and ethical terrain in which attempts to diversify data are located and highlights how merely diversifying genomic data is not sufficient, but it must be done so to a high ethical standard in order to ultimately reduce inequities in genomic medicine.

Introduction

This research is situated within the wider studies that explore ethical considerations surrounding genomic technologies and practices as well as the ethical issues related to diversity across broader health studies (Duster Reference Duster2003, Reference Duster2015; M’Charek, Reference M’Charek2005; Fullwiley, Reference Fullwiley2007; Hammonds and Herzig, Reference Hammonds and Reverby2008; Fujimura and Rajagopalan, Reference Fujimura and Rajagopalan2011; Nelson, Reference Nelson2016). We start from the premise that the majority of genomic data repositories have been sourced from individuals of Northern-European ancestry, which has created a significant gap in our understanding of the role of genetics in health and disease for a global population (Aicardi et al., Reference Aicardi, Del Savio, Dove, Lucivero, Tempini and Prainsack2016; Popejoy and Fullerton, Reference Popejoy and Fullerton2016; Sirugo et al., Reference Sirugo, Williams and Tishkoff2019; Mills and Rahal, Reference Mills and Rahal2020). The impact of the overrepresentation of Northern-European ancestral groups in well-established data repositories, which are often used more readily in research (because of the years of linked data they contain) is far-reaching. It may reduce the generalisability of findings, due to poorer understandings about what variants are common or rare across the underrepresented populations (Petrovski and Goldstein, Reference Petrovski and Goldstein2016, Caswell-Jin et al., Reference Caswell-Jin, Gupta, Hall, Petrovchich, Mills, Kingham, Koff, Chun, Levonian, Lebensohn, Ford and Kurian2018; Kurian et al., Reference Kurian, Ward, Hamilton, Deapen, Abrahamse, Bondarenko, Li, Hawley, Morrow, Jagsi and Katz2018); or it may limit our ability to gain insights about genetic variations in specific ancestries and this in turn can lead to erroneous conclusions around disease pathogenicity (Need and Goldstein, Reference Need and Goldstein2009; Bustamante et al., Reference Wade, López-Beltrán, Restrepo and Santos2011; Petrovski and Goldstein, Reference Petrovski and Goldstein2016). For example, Manrai et al. (Reference Manrai, Funke, Rehm, Olesen, Maron, Szolovits, Margulies, Loscalzo and Kohane2016) demonstrated that genetic variants in hypertrophic cardiomyopathy were wrongly classified as disease-causing due to their rareness in predominantly European datasets, while their prevalence in a global population made disease causation unlikely.

As a result, the recognition of the bias in genomic datasets has led to calls to improve diversity in genomic data (Green et al., Reference Green and Guyer2011; Hindorff et al., Reference Hindorff, Bonham and Ohno-Machado2018; Popejoy et al., Reference Popejoy, Ritter, Crooks, Currey, Fullerton, Hindorff, Koenig, Ramos, Sorokin, Wand, Wright, Zou, Gignoux, Bonham, Plon and Bustamante2018; Fatumo et al., Reference Fatumo, Chikowore, Choudhury, Ayub, Martin and Kuchenbaecker2022). The word diversity is used variably – to denote a range in ethnicity, racial categories, ancestral groups, age, gender, sexual orientation, language, education, access to care, socioeconomic status, social class, disabilities, geography or any other shared characteristics in underrepresented populations. However, in the context of calls for diversity in genomics, diversity is often used in relation to genetic ancestry (and how our ancestors migrated across the globe over millions of years).

The calls to diversity present a range of challenges related to the social, political and historical terrain in which they are situated (Ilkilic and Paul, Reference Ilkilic and Paul2009; George et al., Reference George, Duran and Norris2014; Reardon, Reference Reardon2017). In this article we aimed to identify the ethical issues associated with diversifying data in order to develop new approaches to address them.

Methods

We conducted a qualitative evidence synthesis to investigate the ethical issues surrounding the diversification of genomic data, specifically the inclusion of individuals from historically underserved populations, ethnic and racial minoritised groups, and those experiencing ongoing racial and/or intersectional disadvantage in genomic and wider health studies. An interdisciplinary team with backgrounds ranging from sociology, science and technology studies, sociology of race and ethnicity, philosophy and anthropology, to clinical genetics and genomics medicine statistics undertook the study between March and May 2022 and synthesised evidence in three stages.

Rapid review

We drew on methods of systematic reviews to search for eligible empirical studies on electronic databases, across academic and grey literature (including editorials and conference presentations). We conducted the search using OVID Embase, The Social Science Premium Collection and Web of Science databases (see thesaurus and free text search terms in Supplementary material S1). We applied date and language filters to include English articles that were published between 1st January 2000 and 26th February 2022 and were readily available electronically through institutional subscriptions/direct from the author. We outlined the inclusion criteria (Table 1) using Strech et al.’s (Reference Strech, Synofzik and Marckmann2008) Methodology, Issues, Participants (MIP) model and Butler et al.’s (Reference Butler, Hall and Copnell2016) guide, which were developed iteratively with two researchers piloting 30 abstracts to test and adjust eligibility.

Table 1. Inclusion criteria

In total, 100 articles were included in the rapid review (see Figure 1 for the process, and Supplementary material S2 for full list). The PRISMA-S checklist was used to guide the literature search and reporting on the process (Rethlefsen et al., Reference Rethlefsen, Kirtley, Waffenschmidt, Ayala, Moher, Page and Koffel2021).

Figure 1. The selection processes.

We collaboratively designed and piloted data extraction forms, and thematically analysed the extracted data in meetings using thematic analysis methods (Braun and Clark, Reference Braun and Clarke2012; Terry et al., Reference Terry, Hayfield, Clarke, Braun, Willig and Stainton Rogers2017). The extracted data included any participant concernsFootnote 1 about participation in health and genomics studies that was discussed in the findings, discussions or conclusion sections of the articles, as well as authors’ ethical concerns raised in all sections of the articles.

Diverse data ethics workshop

We presented the preliminary themes generated during the rapid review at an online expert workshop in May 2022. The workshop was attended by seven international academics across the fields of medical ethics and bioethics, women’s studies and health promotion, sociology and law, most of whom have been involved in past or current initiatives that attempt(ed) to diversify genomic data. The workshop aimed to consult with key academic experts in the field about the preliminary findings of the review and to identify gaps in the literature. Experts were all female academics affiliated with universities in the United States of America, the United Kingdom, and Australia. The workshop inherited the weakness of the rapid review, in that the invited academics were from English-speaking countries whose work in the field we were familiar with through the rapid review or beyond. The findings of the review, therefore, mainly stem from authors and workshop experts located in a few countries from the Global North.

Other attendees included four members of Genomics England’s Diverse Data initiative, colleagues from the PHG Foundation, colleagues from the University of Oxford with research expertise at the intersection of health/genomics and ethics, and the members of the review team (n = 17). The workshop explored the themes generated during the rapid review, focusing on the complexity of the topic, especially because some of the issues we anticipated did not appear in empirical literature and may be embedded and hidden within research practices or wider social structures and systems. Conversations were recorded, transcribed and analysed collaboratively by team members to generate key themes.

Post-workshop narrative review

We conducted a post-workshop narrative review to supplement the rapid review and workshop discussions. As Greenhalgh et al. (Reference Greenhalgh, Thorne and Malterud2018) argue, systematic reviews are focused and have summative value, whilst narrative reviews focus on the more interpretative and critical stances designed to enhance understanding. Our rapid review drew on elements of systematic reviews and therefore we considered that our synthesis would benefit from an additional narrative review. Moreover, the search strategy of the rapid review was limited to articles that had genomics and related words in their title and abstract. However, during the screening, it was realised that some of the expected ethical issues were only discussed in the wider health research literature.

The narrative review built on the key themes from the workshop and our research group’s knowledge-base that were missing from the rapid review. We also searched for themes generated from the discussions in the workshop on Google Scholar in the wider health studies. The transcripts of the workshop, including workshop discussions of researchers within our research group, were analysed to identify key themes. These themes were then compared with those themes that emerged from the literature review. For similar themes, any additional issues emerging from the workshop were incorporated. New themes were added to the literature review. For these themes, we conducted snowballing to expand on these newer themes based on discussions of relevant literature supplied by the workshop participants.

Findings

Analysing themes from the rapid review, the expert workshop and the narrative review, we found that ethical issues are interconnected across structural factors and research practices. Structural issues include those related to the politics of knowledge production, existing inequities, and their effects on how the harms and benefits of genomics are distributed. Issues related to research practices include those around reflexivity, exploitative dynamics and prioritising meaningful co-production. In what follows we start by detailing structural issues.

Structural issues

Our synthesis identified two key themes related to the structure of the research from which ethical issues may arise. These key themes are the politics of knowledge production and the implications of existing inequities:

Politics of knowledge production

Our findings showed how the ethical issues related to the structure of research might arise from a failure to recognise and engage with the politics of knowledge production – that is to say, the ways in which knowledge is produced, validated and disseminated, and how these processes are influenced by social, economic, political and cultural factors. Ethical issues may arise from overlooking the politics of knowledge production in different ways:

(1) Data, categorisation and neutrality

The perception of viewing data and technologies as neutral and objective was discussed during the workshop. This perception could prevent researchers from interrogating classification systems, categorisation methods and research designs. In turn, these are key in unpacking societal values embedded in technologies and, if ignored, can risk perpetuating social biases and inequalities. The narrative review echoed these concerns, emphasising that data and technologies cannot be separated from their social context and tend to reflect biases and social inequalities (Bowker and Star, Reference Bowker and Star2000; Gitelman, Reference Gitelman2013; Benjamin, Reference Benjamin2019; Ruppert and Scheel, Reference Ruppert and Scheel2021). For example, classification systems and technical tools used for categorising populations are not neutral and need to be closely examined (Bowker and Star, Reference Bowker and Star2000).Footnote 2 This includes common racial and ethnic categories used for recruiting individuals from underserved groups (Popejoy, Reference Popejoy2022), as well as the concept of genetic ancestry used for genomic analysis (Lewis et al., Reference Lewis, Molina, Appelbaum, Dauda, Di Rienzo, Fuentes, Fullerton, Garrison, Ghosh, Hammonds, Jones, Kenny, Kraft, Lee, Mauro, Novembre, Panofsky, Sohail, Neale and Allen2022). Whilst self-reported racial and ethnic categories can be helpful for studying health inequalities,Footnote 3 they should not be used as mappings based on genetic variation (Shim et al., Reference Shim, Ackerman, Darling, Hiatt and Lee2014),Footnote 4 and therefore, may not help in studying genetic variation across populations.Footnote 5 The narrative review highlighted the need to consider the political implications of such commonly used methods in research. For example, research design might reflect methodological “whiteness,” which fails to acknowledge the role of race in the structuring of the world and knowledge construction (Bhambra, Reference Bhambra2017) in Rai et al. (Reference Rai, H, McManus and Pope2022, p. 4).

(2) Misconceptions of race as a biological category

The rapid review stressed that using social categories in genetic research without considering their contingent and complex nature can lead to misconceptions that race and ethnicity are biological constructs which in turn can perpetuate the stereotyping and objectification of certain groups (Ali-Khan and Daar, Reference Ali-Khan and Daar2010, pp. 26–27; Singh and Steeves, Reference Singh and Steeves2020). Similarly, the narrative review included arguments advocating the need to critically evaluate the use of race in genetic research, explaining that human genetic variation is not adequately captured by social classifications such as race and ethnicity, as there is often greater genetic variation within groups than between them (Lewontin, Reference Lewontin, Dobzhansky, Hecht and Steere1972; Tishkoff and Kidd, Reference Tishkoff and Kidd2004). Despite anti-racist agendas, it was highlighted that genomic research can inadvertently reinforce race as a biological concept when social categories are employed to diversify genomic data (Wade et al., Reference Wade, López-Beltrán, Restrepo and Santos2015, p. 777). For example, clustering genetic ancestry by continent can contribute to the reification of racial categories or increase the likelihood of stereotyping (Lewis et al., Reference Lewis, Molina, Appelbaum, Dauda, Di Rienzo, Fuentes, Fullerton, Garrison, Ghosh, Hammonds, Jones, Kenny, Kraft, Lee, Mauro, Novembre, Panofsky, Sohail, Neale and Allen2022). It is therefore important to be aware of the potential consequences of using social categories in genetic research and to strive for more equitable approaches to understanding genetic variation (Lewis et al., Reference Lewis, Molina, Appelbaum, Dauda, Di Rienzo, Fuentes, Fullerton, Garrison, Ghosh, Hammonds, Jones, Kenny, Kraft, Lee, Mauro, Novembre, Panofsky, Sohail, Neale and Allen2022).

Existing inequities

The effect of underlying power imbalances and existing inequities on the distribution of harms and benefits of research was identified as a theme in both reviews and workshop discussions. Socioeconomic factors like race, ethnicity, social class, citizenship and cultural capital affect participants’ ability to access research benefits (Schulz et al., Reference Schulz, Caldwell and Foster2003), whilst the organisational structure of healthcare services may exclude underserved groups (Halford et al., Reference Halford, Fuller, Lyle and Taylor2019), and curtail targeted health interventions from genomic research for these groups (Hammonds and Reverby, Reference Hammonds and Reverby2019). Moreover, people from underserved groups may endure specific harms such as structural racism and legacies of colonialism that can be grouped into three subthemes.

(1) Legacies of colonialism and structural racism

The workshop and narrative review highlighted the influence of historical trajectories of structural racism, legacies of colonialism and unethical conduct on current experiences of participating in biomedical studies (Harry and Dukepoo, Reference Harry and Dukepoo1998; Bowekaty and Davis, Reference Bowekaty and Davis2003; Strickland, Reference Strickland2006; Washington, Reference Washington2006; Christopher et al., Reference Christopher, Saha, Lachapelle, Jennings, Colclough, Cooper, Cummins, Eggers, Fourstar, Harris, Kuntz, Lafromboise, Laveaux, McDonald, Bird, Rink and Webster2011; Harding et al., Reference Harding, Harper, Stone, Neill Catherine, Berger, Harris and Donatuto2012; Hodge, Reference Hodge2012; Kelley et al., Reference Kelley, Belcourt-Dittloff, Belcourt and Belcourt2013; Morton et al., Reference Morton, Proudfit, Calac, Portillo, Lofton-Fitzsimmons, Molina, Flores, Lawson-Risso and Majel-McCauley2013). The study of genetics has itself played a part in perpetuating racism (Roberts, Reference Roberts2011) and has been used to support racist ideologies (ASHG, 2018). Sometimes this has been explicit; for instance, white nationalists have attempted to use genetic ancestry testing to advance their claims of racial superiority (Harmon, Reference Harmon2017; Panofsky and Donovan, Reference Panofsky and Donovan2019). However, colonial practices have also been perpetuated more inadvertently: The Human Genome Diversity Project (HGDP), which aimed to explore global human genetic diversity, was criticised for resembling activities of European colonialists and had long-lasting implications for trust in researchers (Dodson and Williamson, Reference Dodson and Williamson1999; Greely, Reference Greely2001; TallBear, Reference TallBear2007; Roberts, Reference Roberts2011; Claw et al., Reference Claw, Anderson, Begay, Tsosie, Fox and Garrison2018).

(2) Barriers to participate and benefit from research

The rapid review highlighted that trust issues can be worsened if participants’ healthcare needs are deprioritised in research, especially if genomic services are limited or unaffordable to certain groups (Hiratsuka et al., Reference Hiratsuka, Hahn, Woodbury, Hull, Wilson, Bonham, Dillard, Avey, Beckel-Mitchener, Blome, Claw, Ferucci, Gachupin, Ghazarian, Hindorff, Jooma, Trinidad, Troyer and Walajahi2020). Low participation rates of underserved groups in biomedical research were understood in the narrative review and workshop discussions as not solely due to mistrust in institutions or researcher–participant relations (Katz et al., Reference Katz, Green, Kressin, Claudio, Wang and Russell2007, Reference Katz, Kegeles, Kressin, Green, James, Wang, Russell and Claudio2008; Fisher and Kalbaugh, Reference Fisher and Kalbaugh2011). Rather, structural issues associated with limited access to healthcare services, biased assumptions by healthcare professionals and the need for translation services were considered as potential contributors (Fisher and Kalbaugh, Reference Fisher and Kalbaugh2011; Shim et al., Reference Shim, Bentz, Vasquez, Jeske, Saperstein, Fullerton, Foti, McMahon and Lee2022). Ongoing efforts were deemed necessary to establish trustworthiness (Strickland, Reference Strickland2006; Reverby, Reference Reverby2009).

(3) Diversity in the workforce

Both reviews and the workshop discussions highlighted that underrepresentation of diverse ethnic groups in the genomic workforce and lack of diversity amongst genomic researchers (Bentley et al., Reference Bentley, Callier and Rotimi2020; Lewis-Fernández et al., Reference Lewis-Fernández, Coombs, Balán and Interian2018) play their own part in perpetuating inequities. A diverse workforce was considered crucial for reducing inequities in healthcare and scientific research and realising the promise of genomics (Aviles-Santa et al., Reference Aviles-Santa, Heintzman, Lindberg, Guerrero-Preston, Ramos, Abraido-Lanza, Bull, Falcón, McBurnie, Moy, Papanicolaou, Piña, Popovic, Suglia and Vázquez2017; Atkins et al., Reference Atkins, Kelly, Johnson, Williams, Nelson, Joseph, Jackson, King, Stellmacher, Halty, Tinglin and Gage2020; Hiratsuka et al., Reference Hiratsuka, Hahn, Woodbury, Hull, Wilson, Bonham, Dillard, Avey, Beckel-Mitchener, Blome, Claw, Ferucci, Gachupin, Ghazarian, Hindorff, Jooma, Trinidad, Troyer and Walajahi2020; Bonham and Green, Reference Bonham and Green2021), as well as enhancing innovation and creativity that results from more varied lived experiences and perspectives (Lee et al., Reference Lee, Cho, Kraft, Varsava, Gillespie, Ormond, Wilfond and Magnus2019). The absence of diversity in the workforce has the potential to lead to a loss of voices in developing hypotheses and leading research (Bentley et al., Reference Bentley, Callier and Rotimi2020; Bonham and Green, Reference Bonham and Green2021). The need for a supportive environment and management was perceived necessary for sustaining this diversity. Studies warned about tokenistic attempts at diversification whereby existing power structures and hierarchies remain unchallenged, leading to staff from underserved groups being overburdened with addressing diversity issues (Taylor and de Mendoza, Reference Taylor and de Mendoza2018; Ahsan, Reference Ahsan2022; Jeske et al., Reference Jeske, Vasquez, Fullerton, Saperstein, Bentz, Foti, Shim and Lee2022).

Issues surrounding research practices

Our synthesis identified three key themes related to the practice of research from which ethical issues may arise: (a) reflexivity (b) exploitative practices and (c) co-production and engagement.

Reflexivity

Our findings highlighted how ethical issues related to research practice might arise from a lack of researcher reflexivity. This can occur in four main ways.

(1) Cultural humility

Cultural factors can impact people’s attitudes towards biobanking and the sharing of genomic data (Abadie and Heaney, Reference Abadie and Heaney2015; Anie et al., Reference Anie, Olayemi, Paintsil, Owusu-Dabo, Adeyemo, Sani, Galadanci, Nnodu, Tluway, Adjei, Mensah, Sarfo-Antwi, Nwokobia, Gambo, Benjamin, Salim, Osae- Larbi and Ofori-Acquah2021; Canedo et al., Reference Canedo, Wilkins, Senft, Romero, Bonnet and Schlundt2020; Haring et al., Reference Haring, Henry, Hudson, Rodriguez and Taualii2018; Hiratsuka et al., 2020; Lysaght et al., Reference Lysaght, Ballantyne, Xafis, Ong, Schaefer, Ling, Newson, Khor and Tai2020), as well as access to medical help (Atkins et al., Reference Atkins, Kelly, Johnson, Williams, Nelson, Joseph, Jackson, King, Stellmacher, Halty, Tinglin and Gage2020) and affecting health outcomes more generally (Aviles-Santa et al., Reference Aviles-Santa, Heintzman, Lindberg, Guerrero-Preston, Ramos, Abraido-Lanza, Bull, Falcón, McBurnie, Moy, Papanicolaou, Piña, Popovic, Suglia and Vázquez2017). Incorporating cultural values in research practices was perceived necessary for improving diversity (Jacobs et al., Reference Jacobs, Roffenbender, Collmann, Cherry, Bitsói, Bassett and Evans2010; Aviles-Santa et al., Reference Aviles-Santa, Heintzman, Lindberg, Guerrero-Preston, Ramos, Abraido-Lanza, Bull, Falcón, McBurnie, Moy, Papanicolaou, Piña, Popovic, Suglia and Vázquez2017; Haring et al., Reference Haring, Henry, Hudson, Rodriguez and Taualii2018; Kraft et al., Reference Kraft, Cho, Gillespie, Halley, Varsava, Ormond, Luft, Wilfond and Lee2018; Bentley et al., Reference Bentley, Callier and Rotimi2020; Hiratsuka et al., Reference Hiratsuka, Hahn, Woodbury, Hull, Wilson, Bonham, Dillard, Avey, Beckel-Mitchener, Blome, Claw, Ferucci, Gachupin, Ghazarian, Hindorff, Jooma, Trinidad, Troyer and Walajahi2020; Hendricks-Sturrup and Johnson-Glover, Reference Hausman2021; Fatumo et al., Reference Fatumo, Chikowore, Choudhury, Ayub, Martin and Kuchenbaecker2022). However, some highlighted that using cultural factors for stereotyping and blaming patients for mismanaging disease (Bell et al., Reference Bell, Odumosu, Martinez-Hume, Howard and Hunt2019) should be avoided. Others aspired to integrate cultural factors in their research practices. For example, Beaton et al. (Reference Beaton, Hudson, Milne, Port, Russell, Smith, Toki, Uerata, Wilcox, Bartholomew and Wihongi2017) described a framework for incorporating cultural values in the design of genomic research, and Bonham et al. (Reference Bonham, Citrin, Modell, Franklin, Bleicher and Fleck2009) discussed how deliberation and participatory research methods can be culturally tailored to empower participants to generate policy recommendations.

The workshop discussions and narrative review confirmed the significance of cultural context in research (Arbour and Cook, Reference Arbour and Cook2006; Ilkilic & Paul, Reference Ilkilic and Paul2009), and in clinical practice (Warren and Wilson, Reference Warren and Wilson2013), and advocated prioritising local cultural valuesFootnote 6 and improving cultural humility (Sabatello et al., Reference Sabatello, Blake, Chao, Silverman, Mazzoni, Zhang, Chen and Appelbaum2019). Cultural humility refers to the practice of self-reflection (Tervalon and Murray-García, Reference Tervalon and Murray-García1998), and “learning our own biases, being open to others’ cultures, and committing ourselves to authentic partnership and redressing power imbalances” (Minkler, Reference Minkler2012, p. 6). It emphasises the importance of reflexivity, active listening and taking responsibility for interactions on the side of researchers and research institutions (Minkler, Reference Minkler2012; Isaacson, Reference Isaacson2014; Sabatello et al., Reference Sabatello, Blake, Chao, Silverman, Mazzoni, Zhang, Chen and Appelbaum2019). Many also advocated prioritising local cultural values and accommodating collective considerations, in addition to individual autonomy, in research practices (Emanuel and Weijer, Reference Emanuel, Weijer, Childress, Meslin and Shapiro2005; Tsosie et al., Reference Tsosie, Yracheta and Dickenson2019).Footnote 7

(2) AccessibilityFootnote 8

Both reviews and workshop discussions emphasised the importance of adapting research practices to the needs of different groups and designing accessible communication strategies that ensure critical information is conveyed clearly and effectively (Kobayashi et al., Reference Kobayashi, Boudreault, Hill, Sinsheimer and Christina2013; Campbell et al., Reference Campbell, Susser, Mall, Mqulwana, Mndini, Ntola, Nagdee, Zingela, Van Wyk and Stein2017; Kraft and Doerr, Reference Kraft and Doerr2018; Sabatello et al., Reference Sabatello, Blake, Chao, Silverman, Mazzoni, Zhang, Chen and Appelbaum2019; Hendricks-Sturrup and Johnson-Glover, Reference Hausman2021; Uebergang et al., Reference Uebergang, Best, de Silva and Finlay2021; Garofalo et al., Reference Garofalo, Rosenblum, Zhang, Chen, Appelbaum and Sabatello2022). Such communication strategies were thought to improve the trustworthiness of research (Blanchard et al., Reference Blanchard, Hiratsuka, Beans, Lund, Saunkeah, Yracheta, Woodbury, Blacksher, Peercy, Ketchum, Byars and Spicer2020). However, it was also reported that critical information on genomic health research is sometimes communicated in ways that can cause confusion and misunderstandings for participants, posing barriers for participation in genomic research (Garofalo et al., Reference Garofalo, Rosenblum, Zhang, Chen, Appelbaum and Sabatello2022). Inaccessible facilities, information, transportation and other systematic and institutional factors were reported as barriers to access and participation for people with disabilities (Sabatello et al., Reference Sabatello, Chen, Zhang and Appelbaum2019; Garofalo et al., Reference Garofalo, Rosenblum, Zhang, Chen, Appelbaum and Sabatello2022).

(3) Contextualising participants’ concerns

The rapid review reported concerns about the assumptions made regarding non-participation in genomic studies. Concerns included those related to privacy (Buseh et al., 2013; Abadie and Heaney, Reference Abadie and Heaney2015; Simon et al., Reference Simon, Tom and Dong2017; Garrison et al., Reference Garrison, Barton, Porter, Mai, Burke and Carroll2019; Lee et al., Reference Lee, Cho, Kraft, Varsava, Gillespie, Ormond, Wilfond and Magnus2019; Reddy et al., Reference Reddy, Amarnani, Chen, Dynes, Flores, Moshchinsky, Lee, Kurbatov, Shapira, Vignesh and Martello2020; De Ver Dye et al., Reference De Ver Dye, Tavarez, Ramos, Fernandez, Vega, Ocasio, Avendaño, Cardona Cordero, Hering, Dozier and Groth2021; Hendricks-Sturrup and Johnson-Glover, Reference Hausman2021), stigmatisation (Marsh et al., Reference Marsh, Kombe, Fitzpatrick, Williams, Parker and Molyneux2013; Abadie and Heaney, Reference Abadie and Heaney2015; Faure et al., Reference Faure, Matshabane, Marshall, Appelbaum, Stein, Engel and de Vries2019), commodification of data leading to dispossession (Abadie and Heaney, Reference Abadie and Heaney2015) and re-use of data beyond the scope of the original researchFootnote 9 (de Vries et al., Reference de Vries, Williams, Bojang, Kwiatkowski, Fitzpatrick and Parker2014); for example, by commercialisation of the research and unjust corporate profiteering (Lee et al, Reference Lee, Cho, Kraft, Varsava, Gillespie, Ormond, Wilfond and Magnus2019). It was noted that whilst such concerns may be common amongst other groups, they might be heightened for those from underserved groups due to experiences of stigmatisation, discrimination and prejudicial judgement (Abadie and Heaney, Reference Abadie and Heaney2015),Footnote 10 particularly in cases of disease-related stigma (Ali-Khan and Daar, Reference Ali-Khan and Daar2010; Faure et al., Reference Faure, Matshabane, Marshall, Appelbaum, Stein, Engel and de Vries2019). For example, Schulz et al. (Reference Schulz, Caldwell and Foster2003, p. 165) described that “concerns…included the risk that the racial or ethnic group as a whole would become identified with one or more genetic condition and that this identification would lead to discrimination and further inequality.” The potential harms from stigmatisation may be felt immediately within groups, whereas the benefits of genomic research may take much longer to materialise (Beaton et al., Reference Beaton, Hudson, Milne, Port, Russell, Smith, Toki, Uerata, Wilcox, Bartholomew and Wihongi2017). Furthermore, even when the benefits of the research are more immediate, wider socioeconomic factors may affect people’s ability to access those benefits (Schulz et al., Reference Schulz, Caldwell and Foster2003).

(4) Conceptual clarity

The workshop discussions and the narrative review highlighted the difficulty of measuring diversity, and using any such measurements in different contexts. When discussing the need for diversity in genomic data, it is often implied that we are talking about ancestral diversity (Popejoy et al., Reference Popejoy, Ritter, Crooks, Currey, Fullerton, Hindorff, Koenig, Ramos, Sorokin, Wand, Wright, Zou, Gignoux, Bonham, Plon and Bustamante2018; Mills and Rahal, Reference Mills and Rahal2020). However, there is a lack of conceptual clarity in the language of race, ethnicity and ancestry in genomic studies (Bonham et al., Reference Bonham, Citrin, Modell, Franklin, Bleicher and Fleck2009; Bonham et al., Reference Bonham, Green and Pérez-Stable2018; Birney et al., Reference Birney, Inouye, Raff, Rutherford and Scally2021; Khan et al., Reference Khan, Gogarten, McHugh, Stilp, Sofer, Bowers, Wong, Cupples, Hidalgo, Johnson, McDonald, McGarvey, Taylor, Fullerton, Conomos and Nelson2021). While the use of these terms is evolving (Flanagin et al. Reference Flanagin, Frey and Christiansen2021; Khan et al., Reference Khan, Gogarten, McHugh, Stilp, Sofer, Bowers, Wong, Cupples, Hidalgo, Johnson, McDonald, McGarvey, Taylor, Fullerton, Conomos and Nelson2021), differences in when, where and how they are used remains (Hunt and Megyesi, Reference Hunt and Megyesi2008). There is a tendency to use genetic (biogeographical) ancestry and ethnicity/race interchangeably, leading to conflation between socially constructed notions of race and ethnicity that are tied to identity and biological categories of ancestry (Armitage, Reference Armitage2020). Similarly, terms such as “population” and “community” are also often used without interrogating how they are conceptualised. For example, community might be used to refer to a group of people with geographic proximity, shared characteristics or shared lived experiences (M’charek, 2000).

Exploitative practices

The history of medical research is rife with scandals that harmed individuals and groups.Footnote 11 The narrative review found concerns about “ethics dumping” – where privileged researchers outsource ethically questionable research activity to lower-income or less-privileged settings with less oversight (Nature Editorial, 2022). Concerns were raised about exploitative and inequitable dynamics when researchers from high-income countries work with participants from lower-income countries (Igbe and Adebamowo, Reference Igbe and Adebamowo2012; de Vries et al., Reference de Vries, Williams, Bojang, Kwiatkowski, Fitzpatrick and Parker2014) and in the absence of adequate and culturally appropriate oversight (Tiffin, Reference Tiffin2019). Specifically, without commitment to capacity building, researchers may take advantage of funding and programs from developing regions without contributing to the larger objectives of local communities (Mulder et al., Reference Mulder, Abimiku, Adebamowo, de Vries, Matimba, Olowoyo, Ramsay, Skelton and Stein2018), nor passing them the full benefit of the research (Bentley et al., Reference Bentley, Callier and Rotimi2020).

Co-production and engagement

The narrative review highlighted that a reductionist approach to participant engagementFootnote 12 – one that prioritises, or is limited to, recruitment – can worsen existing and create new forms of inequalities (Moodley and Beyer Reference Moodley and Beyer2019). In their critical reflections about a study that formed part of a randomised control trial, Rai et al. (2022) point to the ways in which standard approaches to participant recruitment prioritise speed and volume of recruitment, with little scope for investing time in more community-based approaches centred on relationship building.Footnote 13 Instead, engagement must be long term and regularly evaluated (US National Academy of Medicine, 2022). Furthermore, limiting engagement to the recruitment stage and applying market research tools and strategies in recruitment such as demographic targeting (Epstein, Reference Epstein2008; Cooper and Waldby, Reference Cooper and Waldby2014) can overlook the fact that often barriers to participation are more structural. Conflating recruitment with engagement can lead to further alienation of groups that are already impacted by historical injustices and, consequently, have implications for trust (Ferryman and Pitcan, Reference Ferryman and Pitcan2018).

The workshop discussions highlighted the significance of acknowledging participants as active researchers and knowledge producers, and emphasised the need for co-production of research together with potential participants. This was suggested to help identify and avoid potential problems around data diversification. The narrative review also revealed the role of academic journals in driving change, as many now take a stand against research practices that only involve local researchers in the research process during recruitment (Nature Editorial, 2022).

Various studies in both reviews advocated community engagement throughout research processes (Boyer et al., Reference Boyer, Dillard, El Woodahl, Thummel and Burke2011; Chadwick et al., Reference Chadwick, Copeland, Daniel, Erb-Alvarez, Felton, Khan, Saunkeah, Wharton and Payan2014; Beans et al., Reference Beans, Saunkeah, Woodbury, Ketchum, Spicer and Hiratsuka2019; Tsosie et al., Reference Tsosie, Yracheta and Dickenson2019; Blanchard et al. Reference Blanchard, Hiratsuka, Beans, Lund, Saunkeah, Yracheta, Woodbury, Blacksher, Peercy, Ketchum, Byars and Spicer2020; Hiratsuka et al., Reference Hiratsuka, Hahn, Woodbury, Hull, Wilson, Bonham, Dillard, Avey, Beckel-Mitchener, Blome, Claw, Ferucci, Gachupin, Ghazarian, Hindorff, Jooma, Trinidad, Troyer and Walajahi2020; Hudson et al., Reference Hudson, Garrison, Sterling, Caron, Fox, Yracheta, Anderson, Wilcox, Arbour, Brown, Taualii, Kukutai, Haring, Te Aika, Baynam, Dearden, Chagné, Malhi, Garba, Tiffin, Bolnick, Stott, Rolleston, Ballantyne, Lovett, David-Chavez, Martinez, Sporle, Walter, Reading and Carroll2020Kaladharan et al., Reference Kaladharan, Vidgen, Pearson, Donoghue, Whiteman, Waddell and Pratt2021), and some incorporated it in the design, development and implementation of their studies (Hiratsuka et al., Reference Hiratsuka, Brown and Dillard2012). The rapid review touched upon the lessons learnt from research initiatives that aspired to prioritise co-production. For example, Kowal (Reference Kowal2019) outlined the ethical issues involved in co-producing the “first Indigenous-governed genome facility in the world” − the National Center for Indigenous Genomics (NCIG), with biosamples held at the Australian National University (ANU).

Limitations

We noted some limitations to our review. Firstly, the rapid review search resulted in papers that were mostly from the USA. Furthermore, the search mainly focused on underrepresentation that was based on gender, race and ethnicity, leaving out other (sometimes) underserved groups such as children, older people, people with mental health conditions, prisoners and so on. Secondly, whilst those invited to the workshop were experts in the field, other key voices such as those from low and middle income countries, and non-English speakers were missing from the workshop due to time and budget limitations. In this sense, the workshop inherited the weakness of the rapid review, in that the invited academics were from English-speaking countries whose work in the field we were familiar with through the rapid review or beyond. The findings of the review, therefore, mainly stem from authors and workshop experts located in a few countries from the Global North and were not first-hand experiences of underserved individuals.

Conclusion

The evidence synthesis identified a number of ethical issues arising from the structure and practice of research. Although structural issues partially inhibit researchers and participants from ethically diversifying genomic data, researchers can and should develop new approaches that improve current practices: Mistrust due to past unethical research conduct, different definitions of knowledge and a tendency to seek technical solutions amongst other factors contribute to the lack of diversity in current genomic repositories. Incorporating cultural humility can help improve the inclusivity and diversity of health and genomic studies. Co-production approaches can also help mitigate some of the ethical issues, and lack of them can worsen existing power imbalances. Improving reflexivity of practices by researchers and research institutions can also help avoid exacerbating existing issues.

Our findings demonstrate that diversifying the data on its own is not enough for addressing health inequities, and diversity must be approached holistically to confront unethical practices by researchers, academic institutions, funding bodies, academic journals and policymakers. Therefore, efforts are needed to diversify data as well as empowerment of underserved groups and engagement with structural issues to address wider inequities. We conclude it is essential to co-create knowledge with potential participants and ensure that the benefits of that knowledge are fed back to diverse populations. To diversify genomics as an enterprise, ethical preparedness must be valued and facilitated, and research cultures established that encourage engagement with ethical issues. Cross-fertilisation of ideas between researchers, participants and theorists is essential for facilitating ethical preparedness (Farsides and Lucassen, Reference Farsides and Lucassen2023). Moreover, interdisciplinary collaborations that accommodate working with different knowledge systems can help go beyond diverse data and towards diverse knowledge making.

In conclusion, it is necessary to broaden the scope of diversity beyond data, and engagement beyond recruitment, to encompass all stages of research, from forming the research questions, to analysis, dissemination and governance.

Open peer review

To view the open peer review materials for this article, please visit http://doi.org/10.1017/pcm.2023.20.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/pcm.2023.20.

Acknowledgements

We wish to thank Prof Jenny Reardon, Dr. Alice Popejoy, Prof Emma Kowal, Dr. Krystal S. Tsosie, Dr. Jenny Douglas, Dr. Maya Sabatello, Dr. Colin Mitchell, Alison Hall, Prof Catherine Pope, Prof Donna Dickenson and Dr. Arzoo Ahmed; for participating in the workshop; many of them also commented on the early stages of this work. We also wish to thank Dr. Helena Carley, Dr. Natalie Banner, Prof Karoline Kuchenbaecker, the Diverse Data team at Genomics England and Bana Alamad for their comments on the earlier drafts, and Vicky Fenerty for their comments on the rapid review’s search strategy.

Author contribution

F.H., K.L., R.H., G.S., S.W., L.B., and A.L. contributed to conceiving the research. F.H., G.S., L.B., R.T., L.V.D.P.T., J.D.G.U., D.K., T.J., N.T-W., E.R.H., F.R.A., Y.E., E.H. and A.L. contributed to the rapid review. All contributed to the workshop. F.H., K.L., R.H., G.S., S.W., L.B., A.L. contributed to the narrative review. F.H., K.L., R.H., G.S., S.W., L.B., M.M. and A.L. were involved in drafting and editing the paper. K.S.T., P.D., M.M., L.N. and A.L. commented on the earlier drafts that shaped the paper. A.L. oversaw the project.

Financial support

A review on the ethical, legal and social issues around diversifying genomic data was commissioned by Genomics England. Additional financial support came through work funded by Wellcome trust grant numbers 205,339/A/16/Z and 208,053/B/17/Z.

Competing interest

This review was commissioned by the Diverse Data initiative at Genomics England in January 2022 to gather evidence and learnings from previous data diversification efforts, to inform the initiative’s design. M.M. is the Programme Lead, and L.N. is the Ethics Lead for the initiative. M.M. and L.N. took part in the workshops and commented on drafts of the paper.

Footnotes

1 Here we use “participants” to refer to the communities that were the focus of the studies.

2 Bowker and Star (Reference Bowker and Star2000) note: “Each standard and each category valorizes some point of view and silences another. This is not inherently a bad thing—indeed it is inescapable. But it is an ethical choice, and as such it is dangerous—not bad, but dangerous. For example, the decision of the U.S. Immigration and Naturalization Service to classify some races and classes as desirable for U.S. residents, and others as not, resulted in a quota system that valued affluent people from northern and western Europe over those (especially the poor) from Africa or South America.” (page 5–6).

3 Because, as studies suggest, racial identity may have biological implications (King et al., Reference King, Murphy and Hoyo2015; Lynch et al., Reference Lynch, Peek, Mitra, Ravichandran, Branas, Spangler, Zhou, Paskett, Gehlert, DeGraffinreid, Rebbeck and Riethman2016).

4 The concept of genetic ancestry used for genomic analysis often does not accurately map to existing population classification systems such as geographical proximity, or racial or ethnic categories (Hindorff et al., Reference Hindorff, Bonham and Ohno-Machado2018; Popejoy et al., Reference Popejoy, Ritter, Crooks, Currey, Fullerton, Hindorff, Koenig, Ramos, Sorokin, Wand, Wright, Zou, Gignoux, Bonham, Plon and Bustamante2018; Fatumo et al., Reference Fatumo, Chikowore, Choudhury, Ayub, Martin and Kuchenbaecker2022). As Lewis et al. (Reference Hiratsuka, Brown and Dillard2022) highlight, in genomics medicine statistics, genetic ancestry may refer to estimates of “genetic similarity between individuals in a dataset.” For example, principal component methods often visualise genetic similarity by clustering individuals from the most commonly used reference populations. A reference genome is assembled from a number of individual donors, for example, the most recent human reference genome GRCh38, is derived from >50 genomic clone libraries (https://www.ncbi.nlm.nih.gov/grc/help/faq/). Given that the reference genome represents a limited number of people, some variations regarded as “reference” will in fact be linked with disease (Chen and Butte, Reference Chen and Butte2011). Outside the realm of genomics statistical methods, a common conceptualisation of genetic ancestry relies on the “continent of origin” which may be partially overlapping racial categories. For more details see Lewis et al. (Reference Lewis, Molina, Appelbaum, Dauda, Di Rienzo, Fuentes, Fullerton, Garrison, Ghosh, Hammonds, Jones, Kenny, Kraft, Lee, Mauro, Novembre, Panofsky, Sohail, Neale and Allen2022).

5 From a clinical perspective it may be useful to know that genetic conditions are more common in people with certain ancestry than others (Kariuki and Williams, Reference Kariuki and Williams2020), but such differences are rarely absolute and too much focus on such information may lead to the condition being missed in populations in which it is often rare.

6 For example, Arbour and Cook (Reference Arbour and Cook2006)‘s “DNA on loan” aims to embed local knowledge, and respect culture in all stages of the research.

7 For different conceptualisations of group harm in genetics research please see Hausman (Reference de Vries, Jallow, Williams, Kwiatkowski, Parker and Fitzpatrick2007).

8 Rio et al. (2016) defined accessibility as a “…state in which an individual’s functional capacity and the functional demands of an environment are matched so the individual can effectively complete an activity.” (p. 2139).

9 A well-known example of this is the Havasupai case. For a detailed account see Drabiak-Syed (Reference Drabiak-Syed2010).

10 Also, de Vries et al. (Reference de Vries, Jallow, Williams, Kwiatkowski, Parker and Fitzpatrick2012) found that although genomics may not create new forms of stigma, it might reinforce existing forms, particularly amongst those from underserved groups.

11 The Tuskegee Syphilis Study serves as a well-documented example. The Tuskegee Syphilis Study was a longitudinal study conducted by the United States Public Health Service in Tuskegee, Alabama, in which approximately 600 African Americans participated between 1932 and 1972. In 1972 it was revealed that the participants had received a dishonest explanation for their involvement in the research, and despite existing treatment for their condition – penicillin – they had been prevented from getting this treatment (Emanuel et al., Reference Emanuel, Grady, Crouch, Lie, Miller and Wendler2008, p. 4), so that the research could continue. In response to the Tuskegee scandal in 1979, the National Commission for the Protection of Human Subjects of Biomedical and Behavioural Research by the US Congress issued the Belmont Report, highlighting respect for persons, beneficence and justice as “the broader ethical principles (to) provide a basis on which specific rules may be formulated, criticised, and interpreted.”

12 Whilst engagement in research is increasingly viewed as an ethical imperative (Moodley and Beyer, Reference Moodley and Beyer2019), there is little consensus about what it means in practice (Blasimme and Vayena, Reference Blasimme and Vayena2016; Majumder et al., Reference Majumder, Bollinger, Villanueva, Deverka and Koenig2019). In this article, we consider engagement as something that needs defining with the individuals and groups whose data are needed for improving diversity and representation, as opposed to being defined by researchers only (Moodley and Beyer, Reference Moodley and Beyer2019).

13 We acknowledge that the term “community” requires problematising that is beyond the scope of this article. What constitutes a community and how might we address the very different types of communities we identify?

References

Abadie, R and Heaney, K (2015) “We can wipe an entire culture”: Fears and promises of DNA biobanking among native Americans. Dialectical Anthropology 39(3), 305320. https://doi.org/10.1007/s10624-015-9391-4.CrossRefGoogle Scholar
Ahsan, S (2022) “EDI”: Endless Distraction and Inaction. They Psychologist- The British Psychological Society (blog). 16 February 2022. Available at https://www.bps.org.uk/psychologist/edi-endless-distraction-and-inaction.Google Scholar
Aicardi, C, Del Savio, L, Dove, ES, Lucivero, F, Tempini, N and Prainsack, B (2016) Emerging ethical issues regarding digital health data. On the World Medical Association Draft Declaration on Ethical Considerations Regarding Health Databases and Biobanks. Croatian Medical Journal 57(2), 207213. https://doi.org/10.3325/cmj.2016.57.207.CrossRefGoogle ScholarPubMed
Ali-Khan, SE and Daar, AS (2010) Admixture mapping: From paradigms of race and ethnicity to population history. The HUGO Journal 4(1–4), 2334. https://doi.org/10.1007/s11568-010-9145-y.CrossRefGoogle ScholarPubMed
Anie, KA, Olayemi, E, Paintsil, V, Owusu-Dabo, E, Adeyemo, TA, Sani, MU, Galadanci, NA, Nnodu, O, Tluway, F, Adjei, DN, Mensah, P, Sarfo-Antwi, J, Nwokobia, H, Gambo, A, Benjamin, A, Salim, A, Osae- Larbi, JA, Ofori-Acquah, SF, On behalf of the SickleGenAfrica Network (2021) Sickle cell disease genomics of Africa (SickleGenAfrica) network: Ethical framework and initial qualitative findings from community engagement in Ghana, Nigeria and Tanzania. BMJ Open 11(7), e048208. https://doi.org/10.1136/bmjopen-2020-048208.CrossRefGoogle ScholarPubMed
Arbour, L and Cook, D (2006) DNA on loan: Issues to consider when carrying out genetic research with aboriginal families and communities. Community Genetics 9(3), 153160. https://doi.org/10.1159/000092651.Google ScholarPubMed
Armitage, H (2020) ‘5 Questions: Alice Popejoy on race, ethnicity and ancestry in science’. Stanford Medicine News Center. 21 August 2020. Available at http://med.stanford.edu/news/all-news/2020/08/alice-popejoy-on-race-ethnicity-and-ancestry-in-science.html.Google Scholar
ASHG (2018) ASHG denounces attempts to link genetics and racial supremacy. American Journal of Human Genetics 103(5), 636. https://doi.org/10.1016/j.ajhg.2018.10.011.CrossRefGoogle Scholar
Atkins, R, Kelly, T-A, Johnson, S, Williams, W, Nelson, Y, Joseph, PV, Jackson, D, King, D, Stellmacher, T, Halty, ND, Tinglin, M and Gage, G (2020) Eliciting willingness and beliefs towards participation in genetic psychiatric testing in black/African American mothers at risk for depression. Behavioral Sciences 10(12):181. https://doi.org/10.3390/bs10120181.CrossRefGoogle ScholarPubMed
Aviles-Santa, ML, Heintzman, J, Lindberg, NM, Guerrero-Preston, R, Ramos, K, Abraido-Lanza, AL, Bull, J, Falcón, A, McBurnie, MA, Moy, E, Papanicolaou, G, Piña, IL, Popovic, J, Suglia, SF and Vázquez, MA (2017) Personalized medicine and Hispanic health: Improving health outcomes and reducing health disparities - A National Heart, Lung, and Blood Institute workshop report. BMC Proceedings 11(Suppl 11), 11. https://doi.org/10.1186/s12919-017-0079-4.CrossRefGoogle ScholarPubMed
Beans, JA, Saunkeah, B, Woodbury, RB, Ketchum, TS, Spicer, PG and Hiratsuka, VY (2019) Community protections in American Indian and Alaska native participatory research—A scoping review. Social Sciences 8(4), 127. https://doi.org/10.3390/socsci8040127.CrossRefGoogle ScholarPubMed
Beans, JA, Woodbury, RB, Wark, KA, Hiratsuka, VY and Spicer, P (2020) Perspectives on precision medicine in a tribally managed primary care setting. AJOB Empirical Bioethics 11(4), 246256. https://doi.org/10.1080/23294515.2020.1817172.CrossRefGoogle Scholar
Beaton, A, Hudson, M, Milne, M, Port, RV, Russell, K, Smith, B, Toki, V, Uerata, L, Wilcox, P, Bartholomew, K and Wihongi, H (2017) Engaging Maori in biobanking and genomic research: A model for biobanks to guide culturally informed governance, operational, and community engagement activities. Genetics in Medicine 19(3), 345351. https://doi.org/10.1038/gim.2016.111.CrossRefGoogle Scholar
Bell, HS, Odumosu, F, Martinez-Hume, AC, Howard, HA and Hunt, LM (2019) Racialized risk in clinical care: Clinician vigilance and patient responsibility. Medical Anthropology 38(3), 224238. https://doi.org/10.1080/01459740.2018.1476508.CrossRefGoogle ScholarPubMed
Benjamin, R (2019) Race after Technology: Abolitionist Tools for the New Jim Code. Cambridge: Polity Press.Google Scholar
Bentley, AR, Callier, SL and Rotimi, CN (2020) Evaluating the promise of inclusion of African ancestry populations in genomics. NPJ Genomic Medicine 5(1), 5. https://doi.org/10.1038/s41525-019-0111-x.CrossRefGoogle ScholarPubMed
Bhambra, GK (2017) Brexit, trump, and “methodological whiteness”: On the misrecognition of race and class. The British Journal of Sociology 68(S1), S214S232. https://doi.org/10.1111/1468-4446.12317.CrossRefGoogle ScholarPubMed
Birney, E, Inouye, M, Raff, J, Rutherford, A and Scally, A (2021) The language of race, ethnicity, and ancestry in human genetic research. arXiv:2106.10041. https://doi.org/10.48550/arXiv.2106.10041.CrossRefGoogle Scholar
Bonham, VL, Citrin, T, Modell, SM, Franklin, TH, Bleicher, EW and Fleck, LM (2009) Community-based dialogue: Engaging communities of color in the United States’ genetics policy conversation. Journal of Health Politics, Policy and Law 34(3), 325359. https://doi.org/10.1215/03616878-2009-009.CrossRefGoogle ScholarPubMed
Blanchard, J, Hiratsuka, V, Beans, JA, Lund, J, Saunkeah, B, Yracheta, J, Woodbury, RB, Blacksher, E, Peercy, M, Ketchum, S, Byars, C and Spicer, P (2020) Power sharing, capacity building, and evolving roles in ELSI: The center for the ethics of indigenous genomic research. Collaborations (Coral Gables, Fla.) 3(1), 18. https://doi.org/10.33596/coll.71.Google Scholar
Blasimme, A and Vayena, E (2016) Becoming partners, retaining autonomy: Ethical considerations on the development of precision medicine. BMC Medical Ethics 17(1), 67. https://doi.org/10.1186/s12910-016-0149-6.CrossRefGoogle ScholarPubMed
Bonham, VL, Green, ED and Pérez-Stable, EJ (2018) Examining how race, ethnicity, and ancestry data are used in biomedical research. JAMA 320(15), 15331534. https://doi.org/10.1001/jama.2018.13609CrossRefGoogle ScholarPubMed
Bonham, VL and Green, ED (eds) (2021) The genomics workforce must become more diverse: A strategic imperative. American Journal of Human Genetics 108(1), 37. https://doi.org/10.1016/j.ajhg.2020.12.013.CrossRefGoogle ScholarPubMed
Bowekaty, MB and Davis, DS (2003) Cultural issues in genetic research with American Indian and Alaskan native people. IRB: Ethics & Human Research 25(4), 1215. https://doi.org/10.2307/3563819.CrossRefGoogle ScholarPubMed
Bowker, GC and Star, SL (2000) Sorting Things Out: Classification and Its Consequences. Cambridge, MA: Inside Technology/MIT Press.CrossRefGoogle Scholar
Boyer, BB, Dillard, D, El Woodahl, RW, Thummel, K and Burke, W (2011) Ethical issues in developing pharmacogenetic research Partnerships with American indigenous communities. Clinical Pharmacology & Therapeutics 89(3), 343345. https://doi.org/10.1038/clpt.2010.303.CrossRefGoogle ScholarPubMed
Braun, V and Clarke, V (2012) Thematic analysis. In APA Handbook of Research Methods in Psychology , Vol. 2 : Research Designs: Quantitative, Qualitative, Neuropsychological, and Biological. Washington DC: American Psychological Association, pp. 5771.Google Scholar
Buseh, AG, Stevens, PE, Millon-Underwood, S, Townsend, L and Kelber, ST (2013) Community leaders’ perspectives on engaging African Americans in biobanks and other human genetics initiatives. Journal of Community Genetics 4(4), 483494. https://doi.org/10.1007/s12687-013-0155-z.CrossRefGoogle ScholarPubMed
Bustamante, CD, Burchard, EG and De la Vega, FM (2011) Genomics for the world. Nature 475(7355), 163165. https://doi.org/10.1038/475163a.CrossRefGoogle ScholarPubMed
Butler, A, Hall, H and Copnell, B (2016) A guide to writing a qualitative systematic review protocol to enhance evidence-based practice in nursing and health care’. Worldviews on Evidence-Based Nursing 13(3), 241249. https://doi.org/10.1111/wvn.12134.CrossRefGoogle ScholarPubMed
Campbell, MM, Susser, E, Mall, S, Mqulwana, SG, Mndini, MM, Ntola, OA, Nagdee, M, Zingela, Z, Van Wyk, S and Stein, DJ (2017) Using iterative learning to improve understanding during the informed consent process in a south African psychiatric genomics study. PLOS One 12(11), e0188466. https://doi.org/10.1371/journal.pone.0188466.CrossRefGoogle Scholar
Canedo, JR, Wilkins, CH, Senft, N, Romero, A, Bonnet, K and Schlundt, D (2020) Barriers and facilitators to dissemination and adoption of precision medicine among Hispanics/Latinos. BMC Public Health 20(1), 603. https://doi.org/10.1186/s12889-020-08718-1.CrossRefGoogle ScholarPubMed
Caswell-Jin, JL, Gupta, T, Hall, E, Petrovchich, IM, Mills, MA, Kingham, KE, Koff, R, Chun, NM, Levonian, P, Lebensohn, AP, Ford, JM and Kurian, AW (2018) Racial/ethnic differences in multiple-gene sequencing results for hereditary cancer risk. Genetics in Medicine: Official Journal of the American College of Medical Genetics 20(2), 234239. https://doi.org/10.1038/gim.2017.96.CrossRefGoogle ScholarPubMed
Chadwick, JQ, Copeland, KC, Daniel, MR, Erb-Alvarez, JA, Felton, BA, Khan, SI, Saunkeah, BR, Wharton, DF and Payan, ML (2014) Partnering in research: A National Research Trial Exemplifying Effective Collaboration with American Indian nations and the Indian Health Service. American Journal of Epidemiology 180(12), 12021207. https://doi.org/10.1093/aje/kwu246.CrossRefGoogle ScholarPubMed
Chen, R and Butte, AJ (2011) The Reference Human Genome Demonstrates High Risk of Type 1 Diabetes and Other Disorders. In Biocomputing 231242. WORLD SCIENTIFIC https://doi.org/10.1142/9789814335058_0025.Google Scholar
Christopher, S, Saha, R, Lachapelle, P, Jennings, D, Colclough, Y, Cooper, C, Cummins, C, Eggers, MJ, Fourstar, K, Harris, K, Kuntz, SW, Lafromboise, V, Laveaux, D, McDonald, T, Bird, JR, Rink, E and Webster, L (2011) Applying indigenous community-based participatory research principles to partnership development in health disparities research. Family & Community Health 34(3), 246255. https://doi.org/10.1097/FCH.0b013e318219606f.CrossRefGoogle ScholarPubMed
Claw, KG, Anderson, MZ, Begay, RL, Tsosie, KS, Fox, K and Garrison, N’A (2018) A framework for enhancing ethical genomic research with indigenous communities. Nature Communications 9(1), 2957. https://doi.org/10.1038/s41467-018-05188-3.CrossRefGoogle ScholarPubMed
Cooper, M and Waldby, C (2014) Clinical Labor: Tissue Donors and Research Subjects in the Global Bioeconomy. Durham, USA: Duke University Press. http://ebookcentral.proquest.com/lib/oxford/detail.action?docID=1632037.Google Scholar
De Ver Dye, T, Tavarez, ZQ, Ramos, JGP, Fernandez, ID, Vega, CV, Ocasio, DMV, Avendaño, E, Cardona Cordero, NR, Hering, CD, Dozier, AM and Groth, SW (2021) Participation in genetic research among Latinx populations by Latin America birth-residency concordance: A global study. Journal of Community Genetics 12(4), 603615. https://doi.org/10.1007/s12687-021-00538-z.CrossRefGoogle ScholarPubMed
de Vries, J, Jallow, M, Williams, TN, Kwiatkowski, D, Parker, M and Fitzpatrick, R (2012) Investigating the potential for ethnic group harm in collaborative genomics research in Africa: Is ethnic stigmatisation likely? Social Science & Medicine 75(8), 14001407. https://doi.org/10.1016/j.socscimed.2012.05.020.CrossRefGoogle ScholarPubMed
de Vries, J, Williams, TN, Bojang, K, Kwiatkowski, DP, Fitzpatrick, R and Parker, M (2014) Knowing who to trust: Exploring the role of “ethical metadata” in mediating risk of harm in collaborative genomics research in Africa. BMC Medical Ethics 15(1), 62. https://doi.org/10.1186/1472-6939-15-62.CrossRefGoogle ScholarPubMed
Dodson, M and Williamson, R (1999) Indigenous peoples and the morality of the human genome diversity project. Journal of Medical Ethics 25(2), 204208. https://doi.org/10.1136/jme.25.2.204.CrossRefGoogle ScholarPubMed
Drabiak-Syed, K (2010) Lessons from Havasupai Tribe v. Arizona State University Board of Regents: Recognizing group, cultural, and dignitary harms as legitimate risks warranting integration into research practice. https://doi.org/10.13016/dhke-perq.CrossRefGoogle Scholar
Duster, T (2003) Backdoor to Eugenics, 2nd Edn. New York: Routledge.Google Scholar
Duster, T (2015) A post-genomic surprise. The molecular reinscription of race in science, law and medicine. The British Journal of Sociology 66(1), 127. https://doi.org/10.1111/1468-4446.12118.CrossRefGoogle ScholarPubMed
Emanuel, EJ, Grady, CC, Crouch, RA, Lie, RK, Miller, FG and Wendler, DD (2008) The Oxford Textbook of Clinical Research Ethics. Cary, NC: Oxford University Press. Available at http://ebookcentral.proquest.com/lib/oxford/detail.action?docID=665420.CrossRefGoogle Scholar
Emanuel, E and Weijer, C (2005) Protecting communities in research: From a new principle to rational protections. In Childress, J, Meslin, E and Shapiro, H (eds), Belmont Revisited: Ethical Principles for Research with Human Subjects. Washington DC: Georgetown University Press.Google Scholar
Epstein, S (2008) The rise of “recruitmentology”: Clinical research, racial knowledge, and the politics of inclusion and difference’. Social Studies of Science 38(5), 801832. https://doi.org/10.1177/0306312708091930.CrossRefGoogle ScholarPubMed
Farsides, B and Lucassen, AM (2023) Ethical preparedness and developments in genomic healthcare. Journal of Medical Ethics. 0:16. https://doi.org/10.1136/jme-2022-108528.Google ScholarPubMed
Fatumo, S, Chikowore, T, Choudhury, A, Ayub, M, Martin, AR and Kuchenbaecker, K (2022) A roadmap to increase diversity in genomic studies. Nature Medicine 28(2), 243250. https://doi.org/10.1038/s41591-021-01672-4.CrossRefGoogle ScholarPubMed
Faure, MC, Matshabane, OP, Marshall, P, Appelbaum, PS, Stein, DJ, Engel, ME and de Vries, J (2019) Does genetics matter for disease-related stigma? The impact of genetic attribution on stigma associated with rheumatic heart disease in the Western cape, South Africa. Social Science & Medicine 243. https://doi.org/10.1016/j.socscimed.2019.112619.CrossRefGoogle ScholarPubMed
Ferryman, K and Pitcan, M (2018) Fairness in Precision Medicine. New York, USA: Data & Society. https://datasociety.net/library/fairness-in-precision-medicine/.Google Scholar
Fisher, JA and Kalbaugh, CA (2011) Challenging assumptions about minority participation in US clinical research. American Journal of Public Health 101(12), 22172222. https://doi.org/10.2105/AJPH.2011.300279.CrossRefGoogle ScholarPubMed
Flanagin, A, Frey, T, Christiansen, SL and AMA Manual of Style Committee (2021) Updated guidance on the reporting of race and ethnicity in medical and science journals. JAMA 326(7), 621627. https://doi.org/10.1001/jama.2021.13304.CrossRefGoogle ScholarPubMed
Fujimura, JH and Rajagopalan, R (2011) Different differences: The use of “genetic ancestry” versus race in biomedical human genetic research. Social Studies of Science 41(1), 530. https://doi.org/10.1177/0306312710379170.CrossRefGoogle ScholarPubMed
Fullwiley, D (2007) The molecularization of race: Institutionalizing human difference in pharmacogenetics practice. Science as Culture 16(1), 130. https://doi.org/10.1080/09505430601180847.CrossRefGoogle Scholar
Garofalo, DC, Rosenblum, HA, Zhang, Y, Chen, Y, Appelbaum, PS and Sabatello, M (2022) Increasing inclusivity in precision medicine research: Views of deaf and hard of hearing individuals. Genetics in Medicine 24(3), 712721. https://doi.org/10.1016/j.gim.2021.11.015CrossRefGoogle ScholarPubMed
Garrison, NA, Barton, KS, Porter, KM, Mai, T, Burke, W and Carroll, SR (2019) Access and management: Indigenous perspectives on genomic data sharing. Ethnicity & Disease 29, 659668. https://doi.org/10.18865/ed.29.S3.659.CrossRefGoogle ScholarPubMed
George, S, Duran, N and Norris, K (2014) A systematic review of barriers and facilitators to minority research participation among African Americans, Latinos, Asian Americans, and Pacific Islanders. American Journal of Public Health 104(2), e16e31. https://doi.org/10.2105/AJPH.2013.301706.CrossRefGoogle ScholarPubMed
Gitelman, L (ed.) (2013) ‘Raw Data’ Is An Oxymoron. Cambridge: The MIT Press. https://doi.org/10.7551/mitpress/9302.001.0001.CrossRefGoogle Scholar
Greely, HT (2001) Human genome diversity: What about the other human genome project? Nature Reviews. Genetics 2(3), 222227. https://doi.org/10.1038/35056071.CrossRefGoogle ScholarPubMed
Green, ED, Guyer, MS and National Human Genome Research Institute (2011) Charting a course for genomic medicine from base pairs to bedside. Nature 470(7333), 204213. https://doi.org/10.1038/nature09764.CrossRefGoogle Scholar
Greenhalgh, T, Thorne, S and Malterud, K (2018) Time to challenge the spurious hierarchy of systematic over narrative reviews?. European Journal of Clinical Investigation 48(6), e12931. https://doi.org/10.1111/eci.12931.CrossRefGoogle ScholarPubMed
Halford, S, Fuller, A, Lyle, K and Taylor, R (2019) Organizing health inequalities? Employee-driven innovation and the transformation of care. Sociological Research Online 24(1), 320. https://doi.org/10.1177/1360780418790272.CrossRefGoogle Scholar
Hammonds, EM and Reverby, SM (2019) Toward a historically informed analysis of racial health disparities since 1619. American Journal of Public Health 109(10), 13481349. https://doi.org/10.2105/AJPH.2019.305262.CrossRefGoogle Scholar
Harding, A, Harper, B, Stone, D, Neill Catherine, O, Berger, P, Harris, S and Donatuto, J (2012) Conducting research with tribal communities: Sovereignty, ethics, and data-sharing issues. Environmental Health Perspectives 120(1), 610. https://doi.org/10.1289/ehp.1103904CrossRefGoogle ScholarPubMed
Haring, RC, Henry, WA, Hudson, M, Rodriguez, EM and Taualii, M (2018) Views on clinical trial recruitment, biospecimen collection, and cancer research: Population science from landscapes of the Haudenosaunee (people of the longhouse). Journal of Cancer Education 33(1), 4451. https://doi.org/10.1007/s13187-016-1067-5.CrossRefGoogle ScholarPubMed
Harmon, A (2017) Why White Supremacists Are Chugging Milk (and Why Geneticists Are Alarmed). The New York Times, 2017, 17 edition. Available at https://www.nytimes.com/2018/10/17/us/white-supremacists-science-dna.html.Google Scholar
Harry, D and Dukepoo, F (1998) Indians, genes and genetics: What Indians should know about the new biotechnology. Indigenous Peoples Coalition Against Biopiracy 7. Available at http://www.ipcb.org/pdf_files/primer.pdf.Google Scholar
Hausman, DM (2007) Group risks, risks to groups, and group engagement in genetics research. Kennedy Institute of Ethics Journal 17(4), 351369. https://doi.org/10.1353/ken.2008.0009.CrossRefGoogle ScholarPubMed
Hendricks-Sturrup, RM and Johnson-Glover, T (2021) African American nurses’ perspectives on genomic medicine research. AMA Journal of Ethics 23(3), E240E251. https://doi.org/10.1001/amajethics.2021.240.Google ScholarPubMed
Hindorff, LA, Bonham, VL and Ohno-Machado, L (2018) Enhancing diversity to reduce health information disparities and build an evidence base for genomic medicine. Personalized Medicine 15(5), 403412. https://doi.org/10.2217/pme-2018-0037.CrossRefGoogle ScholarPubMed
Hiratsuka, V, Brown, J and Dillard, D (2012) Views of biobanking research among Alaska native people: The role of community context. Progress in Community Health Partnerships: Research, Education, and Action 6(2), 131139. https://doi.org/10.1353/cpr.2012.0025.CrossRefGoogle ScholarPubMed
Hiratsuka, VY, Hahn, MJ, Woodbury, RB, Hull, SC, Wilson, DR, Bonham, VL, Dillard, DA; Alaska Native Genomics Research Workshop Group; Avey, JP, Beckel-Mitchener, AC, Blome, J, Claw, K, Ferucci, ED, Gachupin, FC, Ghazarian, A, Hindorff, L, Jooma, S, Trinidad, SB, Troyer, J and Walajahi, H (2020) Alaska native genomic research: Perspectives from Alaska native leaders, Federal Staff, and biomedical researchers. Genetics in Medicine 22(12), 19351943. https://doi.org/10.1038/s41436-020-0926-y.CrossRefGoogle ScholarPubMed
Hodge, FS (2012) No meaningful apology for American Indian unethical research abuses. Ethics & Behavior 22(6), 431444. https://doi.org/10.1080/10508422.2012.730788.CrossRefGoogle Scholar
Hudson, M, Garrison, NA, Sterling, R, Caron, NR, Fox, K, Yracheta, J, Anderson, J, Wilcox, P, Arbour, L, Brown, A, Taualii, M, Kukutai, T, Haring, R, Te Aika, B, Baynam, GS, Dearden, PK, Chagné, D, Malhi, RS, Garba, I, Tiffin, N, Bolnick, D, Stott, M, Rolleston, AK, Ballantyne, LL, Lovett, R, David-Chavez, D, Martinez, A, Sporle, A, Walter, M, Reading, J and Carroll, SR (2020). Rights, interests and expectations: Indigenous perspectives on unrestricted access to genomic data. Nature Reviews Genetics 21(6), 377384. https://doi.org/10.1038/s41576-020-0228-x.CrossRefGoogle ScholarPubMed
Hunt, LM and Megyesi, MS (2008) The ambiguous meanings of the racial/ethnic categories routinely used in human genetics research. Social Science & Medicine 66(2), 349361. https://doi.org/10.1016/j.socscimed.2007.08.034.CrossRefGoogle ScholarPubMed
Igbe, MA and Adebamowo, CA (2012) Qualitative study of knowledge and attitudes to biobanking among lay persons in Nigeria. BMC Medical Ethics 13(1), 27. https://doi.org/10.1186/1472-6939-13-27.CrossRefGoogle ScholarPubMed
Ilkilic, I and Paul, NW (2009) Ethical aspects of genome diversity research: Genome research into cultural diversity or cultural diversity in genome research?. Medicine Health Care and Philosophy 12(1), 2534. https://doi.org/10.1007/s11019-008-9147-x.CrossRefGoogle ScholarPubMed
Isaacson, M (2014) Clarifying concepts: Cultural humility or competency. Journal of Professional Nursing 30(3), 251258. https://doi.org/10.1016/j.profnurs.2013.09.011.CrossRefGoogle ScholarPubMed
Jacobs, B, Roffenbender, J, Collmann, J, Cherry, K, Bitsói, LL, Bassett, K and Evans, CH (2010) Bridging the divide between genomic science and indigenous peoples. Journal of Law, Medicine & Ethics 38(3), 684696. https://doi.org/10.1111/j.1748-720X.2010.00521.x.CrossRefGoogle ScholarPubMed
Jeske, M, Vasquez, E, Fullerton, SM, Saperstein, A, Bentz, M, Foti, N, Shim, JK and Lee, SS-J (2022) Beyond inclusion: Enacting team equity in precision medicine research. PLoS One 17, e0263750. https://doi.org/10.1371/journal.pone.0263750.CrossRefGoogle ScholarPubMed
Kaladharan, S, Vidgen, ME, Pearson, JV, Donoghue, VK, Whiteman, DC, Waddell, N and Pratt, G (2021) Ask the people: Developing guidelines for genomic research with aboriginal and Torres Strait islander peoples. BMJ Global Health 6(11), e007259. https://doi.org/10.1136/bmjgh-2021-007259.CrossRefGoogle ScholarPubMed
Kariuki, SN and Williams, TN (2020) Human genetics and malaria resistance. Human Genetics 139(6), 801811. https://doi.org/10.1007/s00439-020-02142-6.CrossRefGoogle ScholarPubMed
Katz, RV, Green, BL, Kressin, NR, Claudio, C, Wang, MQ and Russell, SL (2007) Willingness of minorities to participate in biomedical studies: Confirmatory findings from a follow-up study using the Tuskegee legacy project questionnaire. Journal of the National Medical Association 99(9), 10521060.Google ScholarPubMed
Katz, RV, Kegeles, SS, Kressin, NR, Green, BL, James, SA, Wang, MQ, Russell, SL and Claudio, C (2008) Awareness of the Tuskegee syphilis study and the US presidential apology and their influence on minority participation in biomedical research. American Journal of Public Health 98(6), 11371142. https://doi.org/10.2105/AJPH.2006.100131.CrossRefGoogle ScholarPubMed
Kelley, A, Belcourt-Dittloff, A, Belcourt, C and Belcourt, G (2013) Research ethics and indigenous communities. American Journal of Public Health 103(12), 21462152. https://doi.org/10.2105/AJPH.2013.301522.CrossRefGoogle ScholarPubMed
Khan, AT, Gogarten, SM, McHugh, CP, Stilp, AM, Sofer, T, Bowers, ML, Wong, Q, Cupples, LA, Hidalgo, B, Johnson, AD, McDonald, MN, McGarvey, ST, Taylor, MRG, Fullerton, SM, Conomos, MP and Nelson, SC (2021) Recommendations on the use and reporting of race, ethnicity, and ancestry in genetic research: Experiences from the NHLBI TOPMed program. Cell Genomics 2(8), 100155. https://doi.org/10.1016/j.xgen.2022.100155.CrossRefGoogle Scholar
King, K, Murphy, S and Hoyo, C (2015) Epigenetic regulation of newborns’ imprinted genes related to gestational growth: Patterning by parental race/ethnicity and maternal socioeconomic status. Journal of Epidemiology and Community Health 69(7), 639647. https://doi.org/10.1136/jech-2014-204781.CrossRefGoogle Scholar
Kobayashi, Y, Boudreault, P, Hill, K, Sinsheimer, JS and Christina, GSP (2013) Using a social marketing framework to evaluate recruitment of a prospective study of genetic counseling and testing for the deaf community. BMC Medical Research Methodology 13. https://doi.org/10.1186/1471-2288-13-145.CrossRefGoogle ScholarPubMed
Kowal, E (2019) Indigenous people and genomics in Australia. Twin Research and Human Genetics 22(5), 332. https://doi.org/10.1017/thg.2019.80.Google Scholar
Kraft, SA, Cho, MK, Gillespie, K, Halley, M, Varsava, N, Ormond, KE, Luft, HS, Wilfond, BS and Lee, SS-J (2018) Beyond consent: Building trusting relationships with diverse populations in precision medicine research. The American Journal of Bioethics 18(4), 320. https://doi.org/10.1080/15265161.2018.1431322.CrossRefGoogle ScholarPubMed
Kraft, SA and Doerr, M (2018) Engaging populations underrepresented in research through novel approaches to consent. American Journal of Medical Genetics Part C: Seminars in Medical Genetics 178(1), 7580. https://doi.org/10.1002/ajmg.c.31600.CrossRefGoogle ScholarPubMed
Kurian, AW, Ward, KC, Hamilton, AS, Deapen, DM, Abrahamse, P, Bondarenko, I, Li, Y, Hawley, ST, Morrow, M, Jagsi, R and Katz, SJ (2018) Uptake, results, and outcomes of germline multiple-gene sequencing after diagnosis of breast Cancer. JAMA Oncology 4(8), 10661072. https://doi.org/10.1001/jamaoncol.2018.0644.CrossRefGoogle ScholarPubMed
Lee, SS-J, Cho, MK, Kraft, SA, Varsava, N, Gillespie, K, Ormond, KE, Wilfond, BS and Magnus, D (2019) “I don’t want to be Henrietta lacks”: Diverse patient perspectives on donating biospecimens for precision medicine research. Genetics in Medicine 21(1), 107113. https://doi.org/10.1038/s41436-018-0032-6.CrossRefGoogle ScholarPubMed
Lewis, ACF, Molina, SJ, Appelbaum, PS, Dauda, B, Di Rienzo, A, Fuentes, A, Fullerton, SM, Garrison, NA, Ghosh, N, Hammonds, EM, Jones, DS, Kenny, EE, Kraft, P, Lee, SS, Mauro, M, Novembre, J, Panofsky, A, Sohail, M, Neale, BM and Allen, DS (2022) Getting genetic ancestry right for science and society. Science (New York, N.Y.) 376(6590), 250252. https://doi.org/10.1126/science.abm7530.CrossRefGoogle ScholarPubMed
Lewis-Fernández, R, Coombs, AA, Balán, IC and Interian, A (2018) Motivational interviewing: Overcoming disparities in pharmacotherapy engagement. The Journal of Clinical Psychiatry 79, 3. https://doi.org/10.4088/JCP.18ac12150.CrossRefGoogle ScholarPubMed
Lewontin, RC (1972) The apportionment of human diversity. In Dobzhansky, T, Hecht, MK and Steere, WC (eds.), Evolutionary Biology. New York, NY: Springer US, pp. 381398. https://doi.org/10.1007/978-1-4684-9063-3_14.CrossRefGoogle Scholar
Lynch, SM, Peek, MK, Mitra, N, Ravichandran, K, Branas, C, Spangler, E, Zhou, W, Paskett, ED, Gehlert, S, DeGraffinreid, C, Rebbeck, TR and Riethman, H (2016) Race, ethnicity, psychosocial factors, and telomere length in a multicenter setting. PLOS One 11(1), e0146723. https://doi.org/10.1371/journal.pone.0146723.CrossRefGoogle Scholar
Lysaght, T, Ballantyne, A, Xafis, V, Ong, S, Schaefer, GO, Ling, JMT, Newson, AJ, Khor, IW and Tai, ES (2020) “Who is watching the watchdog?”: Ethical perspectives of sharing health-related data for precision medicine in Singapore. BMC Medical Ethics 21(1), 118. https://doi.org/10.1186/s12910-020-00561-8.CrossRefGoogle ScholarPubMed
M’Charek, A (2005) The Human Genome Diversity Project: An Ethnography of Scientific Practice, 1st Edn. Cambridge: Cambridge University Press. https://doi.org/10.1017/CBO9780511489167.CrossRefGoogle Scholar
Majumder, MA, Bollinger, JM, Villanueva, AG, Deverka, PA and Koenig, BA (2019) The role of participants in a medical information commons. The Journal of Law, Medicine & Ethics: A Journal of the American Society of Law, Medicine & Ethics 47(1), 5161. https://doi.org/10.1177/1073110519840484.CrossRefGoogle Scholar
Manrai, AK, Funke, BH, Rehm, HL, Olesen, MS, Maron, BA, Szolovits, P, Margulies, DM, Loscalzo, J and Kohane, IS (2016) Genetic misdiagnoses and the potential for health disparities. The New England Journal of Medicine 375(7), 655665. https://doi.org/10.1056/NEJMsa1507092.CrossRefGoogle ScholarPubMed
Marsh, V, Kombe, F, Fitzpatrick, R, Williams, TN, Parker, M and Molyneux, S (2013) Consulting communities on feedback of genetic findings in International Health Research: Sharing sickle cell disease and carrier information in coastal Kenya. BMC Medical Ethics 14(1), 41. https://doi.org/10.1186/1472-6939-14-41.CrossRefGoogle ScholarPubMed
Mills, MC and Rahal, C (2020) The GWAS diversity monitor tracks diversity by disease in real time. Nature Genetics 52(3), 242243. https://doi.org/10.1038/s41588-020-0580-y.CrossRefGoogle ScholarPubMed
Minkler, M (2012) Community Organizing and Community Building for Health and Welfare, 3rd Edn. New Brunswick, NJ: Rutgers University Press.Google Scholar
Morton, DJ, Proudfit, J, Calac, D, Portillo, M, Lofton-Fitzsimmons, G, Molina, T, Flores, R, Lawson-Risso, B and Majel-McCauley, R (2013) Creating research capacity through a tribally based institutional review board. American Journal of Public Health 103(12), 21602164. https://doi.org/10.2105/AJPH.2013.301473.CrossRefGoogle ScholarPubMed
Moodley, K and Beyer, C (2019) Tygerberg research Ubuntu-Inspired community engagement model: Integrating community engagement into genomic biobanking. Biopreservation and Biobanking 17(6), 613624. https://doi.org/10.1089/bio.2018.0136.CrossRefGoogle ScholarPubMed
Mulder, N, Abimiku, A, Adebamowo, SN, de Vries, J, Matimba, A, Olowoyo, P, Ramsay, M, Skelton, M and Stein, DJ (2018) H3Africa: Current perspectives. Pharmacogenomics and Personalized Medicine 11, 5966. https://doi.org/10.2147/PGPM.S141546.CrossRefGoogle ScholarPubMed
Need, AC and Goldstein, DB (2009) Next generation disparities in human genomics: Concerns and remedies. Trends in Genetics: TIG 25(11), 489494. https://doi.org/10.1016/j.tig.2009.09.012.CrossRefGoogle ScholarPubMed
Nelson, A (2016) The Social Life of DNA: Race, Reparations, and Reconciliation after the Genome. Boston: Beacon Press.Google Scholar
Panofsky, A and Donovan, J (2019) Genetic ancestry testing among white nationalists: From identity repair to citizen science. Social Studies of Science 49(5), 653681. https://doi.org/10.1177/0306312719861434.CrossRefGoogle ScholarPubMed
Petrovski, S and Goldstein, DB (2016) Unequal representation of genetic variation across ancestry groups creates healthcare inequality in the application of precision medicine. Genome Biology 17(1), 157. https://doi.org/10.1186/s13059-016-1016-y.CrossRefGoogle ScholarPubMed
Popejoy, AB (2022) Building a trustworthy resource for genomics and medicine. In Conference Presentation presented at the Research for Genomic Equity Conference, London: Genomic England. Available at https://vimeo.com/780831101.Google Scholar
Popejoy, AB and Fullerton, SM (2016) Genomics is failing on diversity. Nature 538(7624), 161164. https://doi.org/10.1038/538161a.CrossRefGoogle ScholarPubMed
Popejoy, AB, Ritter, DI, Crooks, K, Currey, E, Fullerton, SM, Hindorff, LA, Koenig, B, Ramos, EM, Sorokin, EP, Wand, H, Wright, MW, Zou, J, Gignoux, CR, Bonham, VL, Plon, SE, Bustamante, CD; and Clinical Genome Resource (ClinGen) Ancestry and Diversity Working Group (ADWG) (2018) The clinical imperative for inclusivity: Race, ethnicity, and ancestry (REA) in genomics. Human Mutation 39(11), 17131720. https://doi.org/10.1002/humu.23644.CrossRefGoogle ScholarPubMed
Rai, T, H, Lisa, McManus, RJ and Pope, C (2022) ‘What would it take to meaningfully attend to ethnicity and race in health research? Learning from a Trial Intervention Development Study. Sociology of Health & Illness. https://doi.org/10.1111/1467-9566.13431.CrossRefGoogle ScholarPubMed
Reardon, J (2017) The Postgenomic Condition: Ethics, Justice, and Knowledge after the Genome. Chicago, IL: University of Chicago Press. https://doi.org/10.7208/chicago/9780226345192.001.0001.CrossRefGoogle Scholar
Reddy, A, Amarnani, A, Chen, M, Dynes, S, Flores, B, Moshchinsky, A, Lee, YJ, Kurbatov, V, Shapira, I, Vignesh, S and Martello, L (2020) Privacy concerns about personal health information and fear of unintended use of biospecimens impact donations by African American patients. Journal of Cancer Education 35(3), 522529. https://doi.org/10.1007/s13187-019-01491-9.CrossRefGoogle ScholarPubMed
Rethlefsen, ML, Kirtley, S, Waffenschmidt, S, Ayala, AP, Moher, D, Page, MJ, Koffel, JB and PRISMA-S Group (2021) PRISMA-S: An extension to the PRISMA Statement for Reporting Literature Searches in Systematic Reviews. Systematic Reviews 10(1), 39. https://doi.org/10.1186/s13643-020-01542-z.CrossRefGoogle Scholar
Reverby, SM (2009) Examining Tuskegee: The Infamous Syphilis Study and Its Legacy. Chapel Hill: University of North Carolina Press. Print.Google Scholar
Roberts, D (2011 ) Fatal Invention: How Science, Politics, and Big Business Re-Create Race in the Twenty-First Century. New York: The New Press. Available at https://www.proquest.com/docview/2132046579/bookReader?accountid=13042.Google Scholar
Ruppert, ES and Scheel, S (eds.) (2021) Data Practices: Making up a European People. London: Goldsmiths Press.Google Scholar
Sabatello, M, Blake, LA, Chao, A, Silverman, A, Mazzoni, RO, Zhang, Y, Chen, Y and Appelbaum, PS (2019) Including the blind community in precision medicine research: Findings from a National Survey and recommendations. Genetics in Medicine: Official Journal of the American College of Medical Genetics 21(11), 26312638. https://doi.org/10.1038/s41436-019-0533-y.CrossRefGoogle ScholarPubMed
Sabatello, M, Chen, Y, Zhang, Y and Appelbaum, PS (2019) Disability inclusion in precision medicine research: A first National Survey. Genetics in Medicine: Official Journal of the American College of Medical Genetics 21(10), 23192327. https://doi.org/10.1038/s41436-019-0486-1.CrossRefGoogle ScholarPubMed
Schulz, A, Caldwell, C and Foster, S (2003) “What are they going to do with the information?” Latino/Latina and African American perspectives on the human genome project. Health Education & Behavior 30(2), 151169. https://doi.org/10.1177/1090198102251026.CrossRefGoogle Scholar
Shim, JK, Ackerman, SL, Darling, KW, Hiatt, RA and Lee, SS-J (2014) Race and ancestry in the age of inclusion: Technique and meaning in post-genomic science. Journal of Health and Social Behavior 55(4), 504518. https://doi.org/10.1177/0022146514555224.CrossRefGoogle ScholarPubMed
Shim, JK, Bentz, M, Vasquez, E, Jeske, M, Saperstein, A, Fullerton, SM, Foti, N, McMahon, C and Lee, SS-J (2022) Strategies of inclusion: The tradeoffs of pursuing “baked in” diversity through place-based recruitment. Social Science & Medicine 306, 115132. https://doi.org/10.1016/j.socscimed.2022.115132.CrossRefGoogle ScholarPubMed
Simon, MA, Tom, LS and Dong, XQ (2017) Knowledge and beliefs about biospecimen research among Chinese older women in Chicago’s Chinatown. Journals of Gerontology Series A-Biological Sciences and Medical Sciences 72, S41S49. https://doi.org/10.1093/gerona/glw333.CrossRefGoogle ScholarPubMed
Singh, S and Steeves, V (2020) The contested meanings of race and ethnicity in medical research: A case study of the DynaMed point of care tool. Social Science & Medicine 265, 113112. https://doi.org/10.1016/j.socscimed.2020.113112.CrossRefGoogle ScholarPubMed
Sirugo, G, Williams, SM and Tishkoff, SA (2019) The missing diversity in human genetic studies. Cell 177(1), 2631. https://doi.org/10.1016/j.cell.2019.02.048CrossRefGoogle ScholarPubMed
Strech, D, Synofzik, M and Marckmann, G (2008) Systematic reviews of empirical bioethics. Journal of Medical Ethics 34(6), 472477. https://doi.org/10.1136/jme.2007.021709.CrossRefGoogle ScholarPubMed
Strickland, CJ (2006) Challenges in community-based participatory research implementation: Experiences in cancer prevention with Pacific Northwest American Indian tribes. Cancer Control 13(3), 230236. https://doi.org/10.1177/107327480601300312.CrossRefGoogle ScholarPubMed
TallBear, K (2007) Narratives of race and indigeneity in the genographic project. The Journal of Law, Medicine & Ethics: A Journal of the American Society of Law, Medicine & Ethics 35(3), 412424. https://doi.org/10.1111/j.1748-720X.2007.00164.x.CrossRefGoogle ScholarPubMed
Taylor, JY and de Mendoza, VB (2018) Improving-Omics-based research and precision health in minority populations: Recommendations for nurse scientists. Journal of Nursing Scholarship 50(1), 1119. https://doi.org/10.1111/jnu.12358.CrossRefGoogle ScholarPubMed
Terry, G, Hayfield, N, Clarke, V and Braun, V (2017) Thematic analysis. In Willig, C and Stainton Rogers, W (eds.), The SAGE Handbook of Qualitative Research in Psychology, 2nd Edn. London: SAGE Publications, pp. 1737.CrossRefGoogle Scholar
Tervalon, M and Murray-García, J (1998) Cultural humility versus cultural competence: A critical distinction in defining physician training outcomes in multicultural education. Journal of Health Care for the Poor and Underserved 9(2), 117125. https://doi.org/10.1353/hpu.2010.0233.CrossRefGoogle ScholarPubMed
Tiffin, N (2019) Potential risks and solutions for sharing genome summary data from African populations. BMC Medical Genomics 12(1), 152. https://doi.org/10.1186/s12920-019-0604-6.CrossRefGoogle ScholarPubMed
Tishkoff, SA and Kidd, KK (2004) Implications of biogeography of human populations for “race” and medicine. Nature Genetics 36(11), S21S27. https://doi.org/10.1038/ng1438.CrossRefGoogle ScholarPubMed
Tsosie, KS, Yracheta, JM and Dickenson, D (2019) Overvaluing individual consent ignores risks to tribal participants. Nature Reviews. Genetics 20(9), 497498. https://doi.org/10.1038/s41576-019-0161-z.CrossRefGoogle ScholarPubMed
Uebergang, E, Best, S, de Silva, MG and Finlay, K (2021) Understanding genomic health information: how to meet the needs of the culturally and linguistically diverse community-a mixed methods study. Journal of Community Genetics 12(4), 549557. https://doi.org/10.1007/s12687-021-00537-0.CrossRefGoogle ScholarPubMed
US National Academy of Medicine (2022) Assessing meaningful community engagement: A conceptual model to advance health equity through transformed systems for health. Organizing committee for assessing meaningful community engagement in health & health care programs & policies. https://doi.org/10.31478/202202c.CrossRefGoogle Scholar
Wade, P, López-Beltrán, C, Restrepo, E and Santos, RV (2015) Genomic research, publics and experts in Latin America: Nation, race and body. Social Studies of Science 45(6), 775796. https://doi.org/10.1177/0306312715623108.CrossRefGoogle ScholarPubMed
Warren, NS and Wilson, PL (2013) A 10-Point Approach to Cultural Competence in Genetic Counseling. Perspectives in Genetic Counselling. Available at https://www.geneticcounselingtoolkit.com/Edits%2011-2013/COUNSELNG%20ARTICLE%20in%20PGC%202013.pdf.Google Scholar
Washington, HA (2006) Medical Apartheid: The Dark History of the Medical Experimentation on Black Americans from Colonial Times to the Present, 1st Edn. New York: Doubleday.Google Scholar
Figure 0

Table 1. Inclusion criteria

Figure 1

Figure 1. The selection processes.

Supplementary material: File

Hardcastle et al. supplementary material
Download undefined(File)
File 35.5 KB

Author comment: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R0/PR1

Comments

No accompanying comment.

Review: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R0/PR2

Conflict of interest statement

Reviewer declares none.

Comments

The ethical challenges of diversifying genomic data is a highly relevant topic for the journal.

The methodologies applied are adequate considering that this is broadly a systematic literature review.

The literature review is comprehensive and follows Prism guidelines.

However, there are inherent weaknesses with the workshop that should be listed early on in the methodology sections. In particular, it would be good to understand the characteristics of the workshop attendees more clearly: did they come from diverse or underrepresented backgrounds? Was there representation from LMICs? Was there representation of different education levels? Was there user representation?

If none of these, then why not? This would be important to understand in more detail. The authors only mention time and funding constraints. However, a meeting over zoom should allow inclusion of representation of a broad range of different underserved groups with relatively little effort. Analysing the root causes for why the authors could not follow their own principles would be interesting and could have been another output of the workshop. The manuscript would benefit from a summative table of the main obstacles to diversity and proposed solutions.

In the conclusion, personally, I would avoid bringing up examples again to keep the conclusion concise. I liked the final paragraph as it hints to the proposed solutions, but I was looking for suggestions/consensus of HOW these solutions could actually be put into practice and WHY it so difficult to overcome the obstacles (see my previous comment). In addition to mistrust, a different definition of knowledge in different groups (scientific versus indigenous) and a different approach to problem-solving (technology-driven versus holistic) should be discussed as one of the major root causes of the lack of engagement in Western research.

Review: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R0/PR3

Conflict of interest statement

Reviewer declares none.

Comments

This manuscript utilizes a qualitative synthesis design, combining data from three sources to explore the ethical issues arising from attempts to diversify genomic data and include individuals from underserved groups into studies exploring the relationship between genomics and health. The manuscript addresses an important issue in genomics research and has the potential to make an important contribution. There are, however, some major revisions that I recommend prior to publication:

- The introduction is very brief. The current study is insufficiently situated within the scholarly discourses which have been taking place around these topics for over two decades. As such many important works are missing, including, to name a few:

Duster, T. (1990). Backdoor to eugenics. New York: Routledge.

Duster, T. (2015). A post‐genomic surprise. The molecular reinscription of race in science, law and medicine. The British journal of sociology, 66(1), 1-27.

Fujimura, J. H., & Rajagopalan, R. (2011). Different differences: The use of ‘genetic ancestry’ versus race in biomedical human genetic research. Social Studies of Science, 41(1), 5-30.

Fullwiley, D. (2007). The molecularization of race: Institutionalizing human difference in pharmacogenetics practice. Science as Culture, 16(1), 1-30.

Hammonds, E. M., & Herzig, R. M. (2009). The nature of difference: sciences of race in the United States from Jefferson to genomics. Cambridge, MA: MIT Press.

M’charek, A. (2005). The human genome diversity project: An ethnography of scientific practice. Cambridge University Press.

Nelson, A. (2016). The social life of DNA: Race, reparations, and reconciliation after the genome. Beacon Press.

A review of these seminal works might aid in specifying the main research question beyond the aim of generally exploring ethical issues arising from attempts to diversify genomic data. Also, situating the study within these scholarly discourses might aid in making the (novel) contributions of this study clearer.

- Footnotes 1 and 2 contain important insights, consider moving these to the main text.

- p. 5 It is unclear to me who the “participants” are in Table 1. and in the sentence “The extracted data included any participant concerns about participation in health and genomics studies that was discussed in the findings, discussions, or conclusion sections of the articles, as well as authors' ethical concerns raised in all sections of the articles.” Similarly, the term “participant concerns” is unclear, and its link to the results is not discussed (except for p. 12 where again its meaning and use remains unclear to me).

- p. 6. Did the Diverse Data Ethics Workshop experts include people identifying as belonging to populations considered historically underserved, racially or ethnically minoritized, or subject to on-going racial AND/OR intersectional disadvantage. Can you discuss how the composition of the workshop might have informed the results?

- p. 6. Section “3. Post-workshop narrative review” does not reveal much regarding how this narrative review was conducted, this should be in included.

- p. 7. The introduction to the findings is very brief. Maybe a summary of the main findings be added here.

- p. 11 Would it be possible to add an example of a genomics project in which cultural humility was successfully achieved, and that the various elements of this were or should be?

- p. 13: “Similarly, terms such as “population” and “community” are also often used without interrogating how they are conceptualised. For example, community might be used to refer to a group of people with geographic proximity, shared characteristics, or shared lived experiences.” References are missing to important work on this issue. For instance: M’charek, A. (2000). Technologies of population: Forensic DNA testing practices and the making of differences and similarities. Configurations, 8(1), 121-158.

Recommendation: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R0/PR4

Comments

The reviewers have raised some interesting questions and made some useful suggestions that can hopefully be addressed. In particular, some more detailed characterisation of the workshop attendees/participants is required, especially around the diversity represented, and how this may have effected the study.

Decision: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R0/PR5

Comments

No accompanying comment.

Author comment: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R1/PR6

Comments

No accompanying comment.

Review: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R1/PR7

Conflict of interest statement

Reviewer declares none.

Comments

Thank you for spending time to address my comments. I have no further additions to make.

Review: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R1/PR8

Conflict of interest statement

Reviewer declares none.

Comments

All initial points to PCM-23-0018 have been addressed adequately.

Recommendation: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R1/PR9

Comments

Thank you for addressing the reviewer comments. As you can see they are now happy to accept.

Decision: The ethical challenges of diversifying genomic data: A qualitative evidence synthesis — R1/PR10

Comments

No accompanying comment.