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Promoting healthy dietary behaviour through personalised nutrition: technology push or technology pull?

Published online by Cambridge University Press:  24 October 2014

Barbara Stewart-Knox ,
Audrey Rankin ,
Sharron Kuznesof ,
Rui Poínhos ,
Maria Daniel Vaz de Almeida ,
Arnout Fischer  and
Lynn J. Frewer
Barbara Stewart-Knox*
Affiliation:
Division of Psychology, University of Bradford, West Yorkshire BD71DP, UK
Audrey Rankin
Affiliation:
Northern Ireland Centre for Food and Health, University of Ulster, Coleraine BT521SA, UK
Sharron Kuznesof
Affiliation:
Food and Society Group, Newcastle University, Newcastle-Upon-Tyne NE17RU, UK
Rui Poínhos
Affiliation:
Faculty of Nutrition and Food Sciences, University of Porto, 4200-465 Porto, Portugal
Maria Daniel Vaz de Almeida
Affiliation:
Faculty of Nutrition and Food Sciences, University of Porto, 4200-465 Porto, Portugal
Arnout Fischer
Affiliation:
Marketing and Consumer Behaviour, Wageningen University, Wageningen 6706KN, The Netherlands
Lynn J. Frewer
Affiliation:
Food and Society Group, Newcastle University, Newcastle-Upon-Tyne NE17RU, UK
*
*Corresponding author: B. Stewart-Knox, email b.stewart-knox@bradford.ac.uk
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Abstract

The notion of educating the public through generic healthy eating messages has pervaded dietary health promotion efforts over the years and continues to do so through various media, despite little evidence for any enduring impact upon eating behaviour. There is growing evidence, however, that tailored interventions such as those that could be delivered online can be effective in bringing about healthy dietary behaviour change. The present paper brings together evidence from qualitative and quantitative studies that have considered the public perspective of genomics, nutrigenomics and personalised nutrition, including those conducted as part of the EU-funded Food4Me project. Such studies have consistently indicated that although the public hold positive views about nutrigenomics and personalised nutrition, they have reservations about the service providers’ ability to ensure the secure handling of health data. Technological innovation has driven the concept of personalised nutrition forward and now a further technological leap is required to ensure the privacy of online service delivery systems and to protect data gathered in the process of designing personalised nutrition therapies.

Keywords

Personalised nutritionNutrigenomicsBenefitRiskInformation technologyFood4Me
Type
Conference on ‘Changing dietary behaviour: physiology through to practice’
Information
Proceedings of the Nutrition Society , Volume 74 , Issue 2 , May 2015 , pp. 171 - 176
Copyright
Copyright © The Authors 2014 

What is personalised nutrition?

Internet and mobile phone technology has become integral to our daily activities and health and eating behaviour is no exception with recent technical advances having fuelled a drive towards direct-to-consumer (D-T-C) personalised nutrition. Personalised nutrition is an innovative concept that seeks to identify individual nutritional needs based on health status, genotype( Reference Ronteltap and van Trijp 1 ) and/or phenotype( Reference Boland 2 ) and then to provide healthy eating advice that is tailored to suit the individual (Food4me.org). Meanwhile, there is a growing body of evidence for the effectiveness of tailored feedback in bringing about healthy behaviour change( Reference Gordon, Griffin and Wawak 3 Reference de Bourdeaudhuij and Brug 6 ). Surveys of D-T-C services have suggested that they are effective in producing healthy behaviour change in approximately one-third of users( Reference Egglestone, Morris and O'Brien 7 Reference O'Daniel, Haga and Willard 10 ). Awareness of D-T-C genetic tests is increasing among consumers( Reference Finney Rutten, Gollust and Naveed 11 ). Those with a stake-hold in the delivery of personalised nutrition see immense potential to transform preventative and therapeutic nutrition and in doing so, to benefit public health and reduce health costs( Reference Lewis and Burton-Freeman 12 ). Personalised nutrition not only has potential for the tailoring of diet to individual health needs, but also to that of groups of people among the general public( Reference Gibney 13 ). For personalised nutrition intervention to have any real and enduring impact upon public health, however, we need to understand and take into account the public vision for such services( Reference Onwezen, Reinders and van der Lans 14 ). Early D-T-C personalised nutrition initiatives have, on the whole, not been commercially successful. Despite the recent rapid advance in interactive health technology( Reference Lewis and Burton-Freeman 12 ) and the potential for societal benefit, there is a dearth of research in the area of personalised nutrition and nutrigenomics from the perspective of the general public( Reference Su and Lu 15 , Reference de Vrieze, Bouwman and Komduur 16 ). Much of what research exists has focused on genetic testing albeit in various contexts, while fewer studies have considered personalised nutrition in particular.

What do the public think about nutrigenomics?

The future success of personalised nutrition in practice will depend upon the public being ready and able to take up aspects of the technology that are essential to service delivery. Personalised medicine and personalised nutrition share certain technologies. Genetic profiling is common to personalised medicine and nutrition and is likely to be important (along with phenotype, etc.) in informing personalised nutrition initiatives in the future. Understanding attitudes towards genetic testing, therefore, is relevant to understanding public response to nutrigenomics which represents the more ‘medicalised’ level of personalised nutrition provision.

Qualitative enquiry into societal views on genetic testing undertaken in the USA( Reference Glenn, Chawla and Bastani 17 Reference Doukas, Fetters and Coyne 23 ), Australia( Reference Keogh, McClaren and Maskiell 24 ), Switzerland( Reference Vayena, Gourna and Streuli 25 ), the Netherlands( Reference Wijdenes-Pijl, Dondorp and Timmermans 26 ) and the UK( Reference Skirton 27 ), has indicated that people are aware of the potential benefits and hold generally positive attitudes towards genetic testing. Potential drivers of the uptake of genetic testing include own health( Reference Glenn, Chawla and Bastani 17 , Reference Streicher, Sanderson and Jabs 18 , Reference Keogh, McClaren and Maskiell 24 , Reference Hardie 28 , Reference McGowan, Fishman and Lambrix 29 ), the health of other family members and descendants( Reference Glenn, Chawla and Bastani 17 Reference Goldman, Kingdon and Wasser 19 , Reference Keogh, McClaren and Maskiell 24 ), for research purposes( Reference Glenn, Chawla and Bastani 17 , Reference Keogh, McClaren and Maskiell 24 , Reference Su, Howard and Borry 30 ) and curiosity( Reference O'Daniel, Haga and Willard 10 , Reference Streicher, Sanderson and Jabs 18 , Reference Keogh, McClaren and Maskiell 24 , Reference Vayena, Gourna and Streuli 25 , Reference Hardie 28 , Reference Su, Howard and Borry 30 , Reference Basson, Futter and Greenberg 31 ). All these studies, however, also catalogued concerns surrounding the enabling technology. Online privacy and the potential for information to be used by companies for commercial gain or to fall into the hands of insurers, employers or government agencies are among issues that have been consistently raised( Reference Glenn, Chawla and Bastani 17 Reference Skirton 27 , Reference Wilde, Meiser and Mitchell 32 , Reference Nyrhinen, Leino-Kilpi and Hietala 33 ). Aspects of the service delivery system itself may also need to be personalised. Whereas some studies of factors determining uptake of genetic testing( Reference Doukas, Fetters and Coyne 23 , Reference Townsend, Adam and Birch 34 ), have suggested that consumers liked the notion of autonomy and being in control( Reference Nyrhinen, Leino-Kilpi and Hietala 33 ), other works have implied that some consumers would prefer the input of a health professional( Reference Wilde, Meiser and Mitchell 32 , Reference Rew, Mackert and Bonevac 35 , Reference Frazier, Calvin and Mudd 36 ). In view of the differing perspectives, the mode of service delivery may need to be personalised.

Survey studies conducted in the USA( Reference Haga, Barry and Mills 8 , Reference Kerath, Klein and Kern 37 Reference Durfy, Bowen and McTiernan 47 ), Canada( Reference Etchegary, Cappelli and Potter 48 ), Russia( Reference Makeeva, Markova and Roses 49 , Reference Makeeva, Markova and Puzyrev 50 ), Finland( Reference Toiviainen, Jallinoja and Aro 51 , Reference Aro, Hakonen and Hietala 52 ), Sweden( Reference Hoeyer, Olofsson and Mjörndal 53 ), the Netherlands( Reference Morren, Rijken and Baanders 54 ), Australia( Reference Wilde, Meiser and Mitchell 55 ), Canada( Reference Ries, Hyde-Lay and Caulfield 56 ) and the UK( Reference Sanderson, Wardle and Jarvis 57 ) have indicated largely positive attitudes towards genetic testing. The public also appear positive about donating genetic material to biobanks( Reference Goldman, Kingdon and Wasser 19 , Reference Brothers, Morrison and Clayton 58 , Reference Treweek, Doney and Leiman 59 ) and willing to supply genetic material for research purposes( Reference Pulley, Brace and Bernard 60 ). Reasons suggested by the public for taking up genetic testing not only include improving one's own health( Reference Gollust, Gordon and Zayac 61 Reference Cappelli, Surh and Humphreys 64 ), but also of other family members and descendants( Reference Akinleye, Roberts and Royal 62 Reference Bosompra, Flynn and Ashikaga 66 ) . Unsurprisingly, therefore, those with a family history of inherited conditions have been found to have more favourable attitudes towards genetic testing( Reference Catz, Green and Tobin 21 , Reference Wilde, Meiser and Mitchell 55 , Reference Kettis-Lindblad, Ring and Viberth 67 ) and may be willing to pay more( Reference Ries, Hyde-Lay and Caulfield 56 ). A sizeable proportion would avail of genetic testing for no reason other than curiosity( Reference Hull, Sharp and Botkin 42 , Reference Makeeva, Markova and Roses 49 , Reference Makeeva, Markova and Puzyrev 50 , Reference Gollust, Gordon and Zayac 61 , Reference Akinleye, Roberts and Royal 62 , Reference Ormond, Hudgins and Ladd 68 ). Others, on the other hand, may not want to know test results unless treatment was available( Reference Hoeyer, Olofsson and Mjörndal 53 , Reference Morren, Rijken and Baanders 54 ).

Despite generally positive attitudes towards genetic testing, and in keeping with existing qualitative studies into genetic testing (see previous paragraph), quantitative research, mainly surveys conducted over the last couple of decades conducted in the USA( Reference Haga, Barry and Mills 8 , Reference Kerath, Klein and Kern 37 , Reference Ormond, Hudgins and Ladd 68 Reference Neumann, Hammitt and Mueller 71 ), Canada( Reference Etchegary, Cappelli and Potter 48 , Reference Ries, Hyde-Lay and Caulfield 56 ), Australia( Reference Taylor 72 ), Europe( Reference Gaskell, Allum and Stares 73 ), the UK( Reference Treweek, Doney and Leiman 59 ), Finland( Reference Jallinoja, Hakonen and Aro 74 , Reference Hietala, Hakonen and Aro 75 ) and the Netherlands( Reference Henneman, Vermeulen and van El 76 ) also indicate considerable concern among the public about internet privacy, data security, data use and data destiny( Reference McGuire, Diaz and Wang 41 , Reference Peters, Rose and Armstrong 43 , Reference Singer, Antonucci and Hoewyk 44 , Reference Toiviainen, Jallinoja and Aro 51 Reference Ries, Hyde-Lay and Caulfield 56 ). Previous surveys into public attitudes towards genomics( Reference Aro, Hakonen and Hietala 52 , Reference Hoeyer, Olofsson and Mjörndal 53 , Reference Wilde, Meiser and Mitchell 55 , Reference Kettis-Lindblad, Ring and Viberth 67 ), however, have failed to recruit samples that have been representative of the general population, making it difficult to draw firm conclusions as to the response of various societal groups to this emerging technology. Attitudes to genetic testing, however, appear to vary by gender, age and educational level. Males( Reference Haga, Barry and Mills 8 , Reference Aro, Hakonen and Hietala 52 , Reference Sanderson, Wardle and Jarvis 57 , Reference Cherkas, Harris and Levinson 63 ) and older individuals( Reference Finney Rutten, Gollust and Naveed 11 , Reference Kerath, Klein and Kern 37 , Reference Aro, Hakonen and Hietala 52 , Reference Sanderson, Wardle and Jarvis 57 ) appear most favourable towards the notion of genetic testing. Analyses of the impact of education level upon attitudes towards genetic testing have produced mixed results( Reference Finney Rutten, Gollust and Naveed 11 , Reference Catz, Green and Tobin 21 , Reference Hensley Alford, McBride and Reid 40 , Reference Donovan and Tucker 46 , Reference Jonassaint, Santos and Glover 77 Reference Hughes, Gomez-Caminero and Benkendorf 79 ). Those educated to a higher educational level( Reference Catz, Green and Tobin 21 , Reference Goddard, Moore and Ottman 78 ) and those in minority ethnic groups( Reference Peters, Rose and Armstrong 43 , Reference Singer, Antonucci and Hoewyk 44 ) appear particularly concerned over data protection, use and destiny.

What does the public think about personalised nutrition?

Whereas personalised medicine relates genotypic information to propensity for disease, personalised nutrition relates genotypic information to optimal diet and health( Reference Gibney and Walsh 80 ). Personalised nutrition also differs from nutrigenomics in taking a broader view of health and dietary health promotion and considering not only genotype, but also phenotype and lifestyle. This could render personalised nutrition less ethically sensitive and more amenable to public health promotion. However, consumer response to nutrigenomics and personalised nutrition remains an under researched area. Only a handful of qualitative (Morin( Reference Morin 81 )) and survey( Reference Stewart-Knox, Bunting and Gilpin 82 , Reference Roosen, Bruhn and Mecking 83 ) studies have considered the public perspective of nutrigenomics, all of which have indicated that between one-third and a one-half of those surveyed would be willing to avail such services and to follow a tailored diet. Having a health problem was also associated with being positive about receiving genetic-profiling information for the purpose of personalising their diet( Reference Stewart-Knox, Bunting and Gilpin 82 , Reference Roosen, Bruhn and Mecking 83 ). Research conducted in the Netherlands has indicated that consumers may be more amenable towards web-based personalised nutrition if they were in control of the use of the results( Reference Ronteltap, van Trijp and Renes 84 ). In keeping with this notion, other studies have implied that doubts about data security, data use and destiny would deter use of such services( Reference Stewart-Knox, Bunting and Gilpin 82 , Reference Roosen, Bruhn and Mecking 83 ).

The Food4Me project

The EU-funded Food4Me project appears to be the first of its kind to have adopted a mixed, qualitative and quantitative, survey design to gain an understanding of what would determine or deter uptake and compliance with personalised nutrition among the European general public and to establish the best way to deliver such services.

Focus group discussions were held in each of eight European countries (Spain, the UK, Ireland, the Netherlands, Poland, Portugal, Greece and Germany) during early 2012. Discussion was prompted using scenarios that depicted personalised nutrition at three successive levels of ‘medicalisation’ for which lifestyle, phenotypic and genetic information was collected (Food4me.org). The concept of personalised nutrition was viewed positively with potential to enhance health. Discourses arising in all eight countries framed personalised nutrition in terms of perceived benefit and risk( Reference Stewart-Knox, Kuznesof and Robinson 85 ). The sort of benefit expected from personalised nutrition were health related and similar to those which have been previously reported( Reference Gollust, Gordon and Zayac 61 Reference Cappelli, Surh and Humphreys 64 ) and included those related to health and fitness such as losing weight, building muscle, preventing and treating disease. D-T-C personalised nutrition services were likened to ‘the food equivalent of a personal trainer’. Themes otherwise centred on the online delivery technology. The convenience of accessing dietary health services in the comfort of one's own home directly and not having to involve the general practitioner were also considered advantageous. The potential for anonymity afforded by such a system could serve to spare embarrassment and enable greater honesty in reporting dietary health behaviour.

Perceived risks were unrelated to personalised nutrition per se but rather to aspects of the delivery system itself such as those incurred by unwittingly visiting spurious websites or as a consequence of a lack of online security. Although in favour of personalised nutrition, the European public were unanimous across eight countries in expressing negative views on the ability of web-based enabling technology to ensure privacy and overcome issues surrounding data protection, usage and data destiny( Reference Stewart-Knox, Kuznesof and Robinson 85 ). As has been found in previous qualitative studies of genetic testing( Reference Glenn, Chawla and Bastani 17 Reference Skirton 27 , Reference Wilde, Meiser and Mitchell 32 , Reference Nyrhinen, Leino-Kilpi and Hietala 33 ) and nutrigenomics( Reference Stewart-Knox, Bunting and Gilpin 82 ), issues surrounding data mishandling arose with concerns expressed about where information could end up. Possibilities discussed included the potential for commercial exploitation, for example, the selling of data to advertisers or spammers, as well as the more sinister possibility of surveillance purposes by insurers, employers and government agencies.

The next stage in the research process was to determine the distribution and generalisability of these ideas quantitatively. The prior qualitative research findings were used to inform the selection of items and validated scales and for inclusion in the Food4Me survey. The resultant questionnaire was translated and back-translated into the native languages of each of the nine EU countries (Germany, Greece, Ireland, Poland, Portugal, Spain, the Netherlands, the UK and Norway) involved in the study. Members of the European public (n 9381) were quota sampled to be nationally representative for each country, on sex, age and education level and then surveyed online during February and March 2013. Similar to the previous surveys of public opinion of genetic testing( Reference McGuire, Diaz and Wang 41 , Reference Peters, Rose and Armstrong 43 , Reference Singer, Antonucci and Hoewyk 44 , Reference Toiviainen, Jallinoja and Aro 51 Reference Ries, Hyde-Lay and Caulfield 56 ), the Food4Me survey found that perceived benefit was associated with intention to take up personalised nutrition. Statistical modelling suggested that the benefit attributed to personalised nutrition contributed to more favourable attitude towards and intention to adopt personalised nutrition( Reference Poínhos, van der Lans and Rankin 86 ). Perceived benefit was also associated with less perceived risk. Perceived risk was unrelated to intention to take up personalised nutrition. A possible explanation for this finding, and one suggested by the prior qualitative research, is that risk was not actually related to the concept of personalised nutrition but to the online delivery technology.

The Food4Me results, therefore, agree with those of previous studies that have investigated attitudes to genetic testing in suggesting that the public are acutely aware of the threat for data mishandling and misuse. Together, the qualitative and survey results suggest that to encourage uptake of personalised nutrition and enable people to achieve healthy dietary change, we must emphasise benefits while making the delivery system secure. Participants taking part in the initial qualitative studies were able to make suggestions as to how to minimise the damage should a privacy or data-handling mishap occur, for example, storing demographic, lifestyle and biological data separately. Nevertheless, the issue of how to ensure online privacy and protect and control data usage and destiny remains.

What does the future hold for personalised nutrition?

Previous research findings provide some clues as to why despite evidence that tailored interventions are effective in bringing about healthy behaviour change, early attempts to deliver personalised nutrition services on a commercial scale have failed. Expectancy value theories allow us to consider the implications of these findings for behaviour change. Protection motivation theory( Reference Maddux and Rogers 87 Reference Floyd, Prentice-Dunn and Rogers 89 ) holds that the likelihood of a behaviour occurring, for example, taking up personalised nutrition, will depend upon the perceived size, severity and likelihood of any associated risk and perceived ability to reduce the risk. This implies a need for further consumer research to establish the perceived size, severity and likelihood of risk associated with online D-T-C personalised nutrition as well as perceived ability to reduce the risk and interaction with perceived benefit.

The overarching message from the research into the public response to genetic testing, nutrigenomics and personalised nutrition is that for D-T-C personalised nutrition to be taken up on a societal scale, people will need assurances that all online interactions would be private and that the provider will have ability to effectively handle and protect information collected in the endeavour to design personalised diets. In the wake of accidents resulting in public data falling into the ‘wrong’ hands and recent revelations about how data generated through social media and other personal internet activities is used for marketing purposes and commercial gain, perceived weaknesses inherent in such technology are likely to limit the future development, consumer uptake and growth of such services.

Potential consumers, although positive about the concept of personalised nutrition, are telling us that in order for them to take up such services the information collected will require regulation( Reference Ahlgren, Nordgren and Perrudin 90 ). Control of the handling and use of health-related data will only be effective if the technology is in place to enable compliance with regulation( Reference Bollinger, Green and Kaufman 91 ). Interdisciplinary research and innovation is needed urgently to render the delivery of health systems such as personalised nutrition secure and enable this potentially important public health innovation. Delivering personalised nutrition to the public will require working closely with information technologists in getting the delivery system perfected. Technological innovation has driven the concept of D-T-C health systems. The future of personalised nutrition would also appear to lie in the hands of information technologists. Meanwhile, promotion of personalised nutrition to the general public would do well to emphasise the (personal) benefits of personalised nutrition.

Acknowledgements

The authors would like to take this opportunity to acknowledge the work of the focus group moderators, observers and transcribers for their input into the qualitative study as well as GfK who undertook sampling and data collection.

Financial Support

The Food4Me project received funding from the European Union's Seventh Framework Programme for research, technological development and demonstration under grant agreement no. 265494.

Conflict of Interest

None.

Authorship

B. S.-K. drafted the manuscript and A. R. collected and reviewed the literature. All authors contributed to the design of the Food4Me studies and data collection. L. F. led the work.

References

1. Ronteltap, A & van Trijp, H (2007) Consumer acceptance of personalised nutrition. Genes Nutr 2, 8587.CrossRefGoogle ScholarPubMed
2. Boland, M (2008) Innovation in the food industry: personalised nutrition and mass customisation. Innov-Manag Policy Pract 10, 5360.CrossRefGoogle Scholar
3. Gordon, E, Griffin, G, Wawak, L et al. (2012) It's not like judgment day: public understanding of and reactions to personalized genomic risk information. J Genet Couns 21, 423432.CrossRefGoogle Scholar
4. Webb, TL, Joseph, J, Yardley, L et al. (2010) Using the internet to promote health behaviour change: a systematic review and meta-analysis, of the impact of theoretical basis, use of behaviour change techniques and mode of delivery on efficacy. J Med Internet Res 12, e4.CrossRefGoogle Scholar
5. Elder, JP, Ayala, GX, Slymen, DJ et al. (2009) Evaluating psychosocial and behavioral mechanisms of change in a tailored communication intervention. Health Educ Behav 36, 366380.CrossRefGoogle Scholar
6. de Bourdeaudhuij, I & Brug, J (2000) Tailoring dietary feedback to reduce fat intake: an intervention at the family level. Health Educ Res 15, 449462.CrossRefGoogle ScholarPubMed
7. Egglestone, C, Morris, A & O'Brien, A (2013) Effect of direct-to-consumer genetic tests on health behaviour and anxiety: a survey of consumers and potential consumers. J Genet Couns 22, 565575.CrossRefGoogle ScholarPubMed
8. Haga, SB, Barry, WT, Mills, R et al. (2013) Public knowledge of and attitudes toward genetics and genetic testing. Genet Test Mol Bioma 17, 327335.CrossRefGoogle ScholarPubMed
9. Kaufman, DJ, Bollinger, JM, Dvoskin, RL et al. (2012) Risky business: risk perception and the use of medical services among customers of DTC personal genetic testing. J Genet Couns 21, 413422.CrossRefGoogle ScholarPubMed
10. O'Daniel, JM, Haga, SB & Willard, HF (2010) Considerations for the impact of personal genome information: a study of genomic profiling among genetics and genomics professionals. J Genet Couns 19, 387401.CrossRefGoogle ScholarPubMed
11. Finney Rutten, LJ, Gollust, SE, Naveed, S et al. (2012) Increasing public awareness of direct-to-consumer genetic tests: health care access, internet use, and population density correlates. J Cancer Epidemiol 2012, 309109.CrossRefGoogle ScholarPubMed
12. Lewis, KD & Burton-Freeman, BM (2010) The role of innovation and technology in meeting individual nutritional needs. J Nutr 140, 426S436S.CrossRefGoogle ScholarPubMed
13. Gibney, MJ (2010) Personalised nutrition: diet, phenotype and genes. J Nutrigenet Nutrigenomics 3, 58.Google Scholar
14. Onwezen, MC, Reinders, MJ, van der Lans, IA et al. (2012) A cross-national consumer segmentation based on food benefits: the link with consumption situations and food perceptions. Food Qual Prefer 24, 276286.CrossRefGoogle Scholar
15. Su, HL & Lu, TJ (2012) Exploring the consumer acceptance of and preferences in nutrigenomics-based personalized health management service. Proc PICMET 2012, 30503058.Google Scholar
16. de Vrieze, J, Bouwman, L, Komduur, R et al. (2009) Nutrition tailored to the individual? Not just yet – Realigning nutrigenomic science with contemporary society. J Nutrigenet Nutrigenomics 2, 184188.Google Scholar
17. Glenn, BA, Chawla, N & Bastani, R (2012) Barriers to genetic testing for breast cancer risk among ethnic minority women: an exploratory study. Ethnic Dis 22, 267273.Google ScholarPubMed
18. Streicher, SA, Sanderson, SC, Jabs, EW et al. (2011) Reasons for participating and genetic information needs among racially and ethnically diverse biobank participants: a focus group study. J Commun Genet 2, 153163.CrossRefGoogle ScholarPubMed
19. Goldman, RE, Kingdon, C, Wasser, J et al. (2008) Rhode Islanders’ attitudes towards the development of a statewide genetic biobank. Pers Med 5, 339359.CrossRefGoogle ScholarPubMed
20. Bates, BR, Lynch, JA, Bevan, JL et al. (2005) Warranted concerns, warranted outlooks: a focus group study of public understanding of genetic research. Soc Sci Med 60, 331344.CrossRefGoogle ScholarPubMed
21. Catz, DS, Green, NS, Tobin, JN et al. (2005) Attitudes about genetics in underserved, culturally diverse populations. Commun Genet 8, 161172.Google ScholarPubMed
22. Rose, AL, Peters, N, Shea, JA et al. (2005) Attitudes and misconceptions about predictive genetic testing for cancer risk. Commun Genet 8, 145151.Google ScholarPubMed
23. Doukas, DJ, Fetters, MD, Coyne, JC et al. (2000) How men view genetic testing for prostate cancer risk: findings from focus groups. Clin Genet 58, 169176.CrossRefGoogle ScholarPubMed
24. Keogh, L, McClaren, B, Maskiell, J et al. (2011) How do individuals decide whether to accept or decline an offer of genetic testing for colorectal cancer? Hered Cancer Clin Pract 9, 17.CrossRefGoogle Scholar
25. Vayena, E, Gourna, E, Streuli, J et al. (2012) Experiences of early users of direct-to-consumer genomics in Switzerland: an exploratory study. Public Health Genomics 15, 352362.CrossRefGoogle ScholarPubMed
26. Wijdenes-Pijl, M, Dondorp, WJ, Timmermans, DRM et al. (2011) Lay perceptions of predictive testing for diabetes based on DNA test results versus family history assessment: a focus group study. BMC Public Health 11, 535.CrossRefGoogle ScholarPubMed
27. Skirton, H (2006) A legacy for the children – attitudes of older adults in the United Kingdom to genetic testing. J Clin Nurs 15, 565573.CrossRefGoogle ScholarPubMed
28. Hardie, EA (2011) Australian community responses to the use of genetic testing for personalised health promotion. Aust J Psychol 63, 119129.CrossRefGoogle Scholar
29. McGowan, ML, Fishman, JR & Lambrix, MA (2010) Personal genomics and individual identities: motivations and moral imperatives of early users. New Genet Soc 29, 261290.CrossRefGoogle ScholarPubMed
30. Su, Y, Howard, HC & Borry, P (2011) Users' motivations to purchase direct-to-consumer genome-wide testing: an exploratory study of personal stories. J Commun Genet 2, 135146.CrossRefGoogle ScholarPubMed
31. Basson, F, Futter, MJ & Greenberg, J (2007) Qualitative research methodology in the exploration of patients' perceptions of participating in a genetic research program. Ophthal Genet 28, 143149.CrossRefGoogle Scholar
32. Wilde, A, Meiser, B, Mitchell, PB et al. (2010) Public interest in predictive genetic testing, including direct-to-consumer testing, for susceptibility to major depression: preliminary findings. Eur J Hum Genet 18, 4751.CrossRefGoogle ScholarPubMed
33. Nyrhinen, T, Leino-Kilpi, H & Hietala, M (2004) Ethical issues in the diagnostic genetic testing process. New Genet Soc 23, 7387.CrossRefGoogle ScholarPubMed
34. Townsend, A, Adam, S, Birch, PH et al. (2012) “I want to know what's in Pandora's box”: comparing stakeholder perspectives on incidental findings in clinical whole genomic sequencing. Am J Med Genet 158A, 25192525.CrossRefGoogle ScholarPubMed
35. Rew, L, Mackert, M & Bonevac, D (2010) Cool, but is it credible? Adolescents’ and parents’ approaches to genetic testing. West J Nurs Res 32, 610627.CrossRefGoogle ScholarPubMed
36. Frazier, L, Calvin, AO, Mudd, GT et al. (2006) Understanding of genetics among older adults. J Nurs Scholarsh 38, 126132.CrossRefGoogle ScholarPubMed
37. Kerath, SM, Klein, G, Kern, M et al. (2013) Beliefs and attitudes towards participating in genetic research – a population based cross-sectional study. BMC Public Health 13, 114.CrossRefGoogle ScholarPubMed
38. Perez, GK, Cruess, DG, Cruess, S et al. (2011) Attitudes toward direct-to-consumer advertisements and online genetic testing among high-risk women participating in a hereditary cancer clinic. J Health Commun 16, 607628.CrossRefGoogle Scholar
39. Falcone, DC, Wood, EM, Xie, SX et al. (2011) Genetic testing and Parkinson disease: assessment of patient knowledge, attitudes, and interest. J Genet Couns 20, 384395.CrossRefGoogle ScholarPubMed
40. Hensley Alford, S, McBride, CM, Reid, RJ et al. (2011) Participation in genetic testing research varies by social group. Public Health Genomics 14, 8593.CrossRefGoogle ScholarPubMed
41. McGuire, AL, Diaz, CM, Wang, T et al. (2009) Social networkers’ attitudes toward direct-to-consumer personal genome testing. Am J Bioethics 9, 310.CrossRefGoogle ScholarPubMed
42. Hull, SC, Sharp, RR, Botkin, JR et al. (2008) Patients' views on identifiability of samples and informed consent for genetic research. Am J Bioethics 8, 6270.CrossRefGoogle ScholarPubMed
43. Peters, N, Rose, R & Armstrong, K (2004) The association between race and attitudes about predictive genetic testing. Cancer Epidemiol Biomarkers Prev 13, 361365.CrossRefGoogle ScholarPubMed
44. Singer, E, Antonucci, T & Hoewyk, JV (2004) Racial and ethnic variations in knowledge and attitudes about genetic testing. Genet Test 8, 3144.CrossRefGoogle ScholarPubMed
45. Press, NA, Yasui, Y, Reynolds, S et al. (2001) Women's interest in genetic testing for breast cancer susceptibility may be based on unrealistic expectations. Am J Med Genet 99, 99110.3.0.CO;2-I>CrossRefGoogle ScholarPubMed
46. Donovan, KA & Tucker, DC (2000) Knowledge about genetic risk for breast cancer and perceptions of genetic testing in a sociodemographically diverse sample. J Behav Med 23, 1536.CrossRefGoogle Scholar
47. Durfy, SJ, Bowen, DJ, McTiernan, A et al. (1999) Attitudes and interest in genetic testing for breast and ovarian cancer susceptibility in diverse groups of women in western Washington. Cancer Epidemiol Biomarkers Prev 8, 369375.Google ScholarPubMed
48. Etchegary, H, Cappelli, M, Potter, B et al. (2010) Attitude and knowledge about genetics and genetic testing. Public Health Genomics 13, 8088.CrossRefGoogle ScholarPubMed
49. Makeeva, OA, Markova, VV, Roses, AD et al. (2010) An epidemiologic-based survey of public attitudes towards predictive genetic testing in Russia. Pers Med 7, 291300.Google ScholarPubMed
50. Makeeva, OA, Markova, VV & Puzyrev, VP (2009) Public interest and expectations concerning commercial genotyping and genetic risk assessment. Pers Med 6, 329341.CrossRefGoogle ScholarPubMed
51. Toiviainen, H, Jallinoja, P, Aro, AR et al. (2003) Medical and lay attitudes towards genetic screening and testing in Finland. Eur J Hum Genet 11, 565572.CrossRefGoogle ScholarPubMed
52. Aro, AR, Hakonen, A, Hietala, M et al. (1997) Acceptance of genetic testing in a general population: age, education and gender differences. Patient Educ Couns 32, 4149.CrossRefGoogle Scholar
53. Hoeyer, K, Olofsson, BO, Mjörndal, T et al. (2004) Informed consent and biobanks: a population-based study of attitudes towards tissue donation for genetic research. Scand J Public Health 32, 224229.CrossRefGoogle ScholarPubMed
54. Morren, M, Rijken, M, Baanders, AN et al. (2007) Perceived genetic knowledge, attitudes towards genetic testing, and the relationship between these among patients with a chronic disease. Patient Educ Couns 65, 197204.CrossRefGoogle ScholarPubMed
55. Wilde, A, Meiser, B, Mitchell, PB et al. (2011) Community interest in predictive genetic testing for susceptibility to major depressive disorder in a large national sample. Psychol Med 41, 16051613.CrossRefGoogle Scholar
56. Ries, NM, Hyde-Lay, R & Caulfield, T (2010) Willingness to pay for genetic testing: a study of attitudes in a Canadian population. Public Health Genomics 13, 292300.CrossRefGoogle Scholar
57. Sanderson, S, Wardle, J, Jarvis, M et al. (2004) Public interest in genetic testing for susceptibility to heart disease and cancer: a population-based survey in the UK. Prev Med 39, 458464.CrossRefGoogle Scholar
58. Brothers, KB, Morrison, DR & Clayton, EW (2011) Two large-scale surveys on community attitudes toward an opt-out biobank. Am J Med Genet A 155A, 29822990.CrossRefGoogle ScholarPubMed
59. Treweek, S, Doney, A & Leiman, D (2009) Public attitudes to the storage of blood left over from routine general practice tests and its use in research. J Health Serv Res Pol 14, 1319.CrossRefGoogle Scholar
60. Pulley, JM, Brace, MM, Bernard, GR et al. (2008) Attitudes and perceptions of patients towards methods of establishing a DNA biobank. Cell Tissue Bank 9, 5565.CrossRefGoogle ScholarPubMed
61. Gollust, SE, Gordon, ES, Zayac, C et al. (2012) Motivations and perceptions of early adopters of personalized genomics: perspectives from research participants. Public Health Genomics 15, 2230.CrossRefGoogle ScholarPubMed
62. Akinleye, I, Roberts, JS, Royal, CDM et al. (2011) Differences between African American and white research volunteers in their attitudes, beliefs and knowledge regarding genetic testing for Alzheimer's disease. J Genet Couns 20, 650659.CrossRefGoogle ScholarPubMed
63. Cherkas, LF, Harris, JM, Levinson, E et al. (2010) A survey of UK public interest in internet-based personal genome testing. PLoS ONE 5, e13473.CrossRefGoogle ScholarPubMed
64. Cappelli, M, Surh, L, Humphreys, L et al. (1999) Psychological and social determinants of women's decisions to undergo genetic counseling and testing for breast cancer. Clin Genet 55, 419430.CrossRefGoogle ScholarPubMed
65. Esplen, M, Madlensky, L, Aronson, M et al. (2007) Colorectal cancer survivors undergoing genetic testing for hereditary non-polyposis colorectal cancer: motivational factors and psychosocial functioning. Clin Genet 72, 394401.CrossRefGoogle ScholarPubMed
66. Bosompra, K, Flynn, BS, Ashikaga, T et al. (2000) Likelihood of undergoing genetic testing for cancer risk: a population- based study. Prev Med 30, 155166.CrossRefGoogle ScholarPubMed
67. Kettis-Lindblad, A, Ring, L, Viberth, E et al. (2005) Genetic research and donation of tissue samples to biobanks. What do potential sample donors in the Swedish general public think? Eur J Public Health 16, 433440.CrossRefGoogle ScholarPubMed
68. Ormond, KE, Hudgins, L, Ladd, JM et al. (2011) Medical and graduate students’ attitudes toward personal genomics. Genet Med 13, 400408.CrossRefGoogle ScholarPubMed
69. Horn, EJ & Terry, SF (2012) Consumer perceptions of genetic testing. Genet Test Mol Biomarkers 16, 463464.CrossRefGoogle ScholarPubMed
70. Apse, KA, Biesecker, BB, Giardiello, FM et al. (2004) Perceptions of genetic discrimination among at-risk relatives of colorectal cancer patients. Genet Med 6, 510516.CrossRefGoogle ScholarPubMed
71. Neumann, P, Hammitt, J, Mueller, C et al. (2001) Public attitudes about genetic testing for Alzheimer's disease. Health Aff 20, 252264.CrossRefGoogle ScholarPubMed
72. Taylor, S (2011) A population-based survey in Australia of men's and women's perceptions of genetic risk and predictive genetic testing and implications for primary care. Public Health Genomics 14, 325336.CrossRefGoogle ScholarPubMed
73. Gaskell, G, Allum, N & Stares, S (2003) Europeans and biotechnology in 2002, Eurobarometer 58·0 (pp. 44). http://ec.europa.eu/publicopinion/archives/ebs/ebs177en.pdf Google Scholar
74. Jallinoja, P, Hakonen, A, Aro, AR et al. (1998) Attitudes towards genetic testing: analysis of contradictions. Soc Sci Med 46, 13671374.CrossRefGoogle ScholarPubMed
75. Hietala, M, Hakonen, A, Aro, AR et al. (1995) Attitudes toward genetic testing among the general-population and relatives of patients with a severe genetic-disease – A survey from Finland. Am J Hum Genet 56, 14931500.Google Scholar
76. Henneman, L, Vermeulen, E, van El, CG et al. (2012) Public attitudes towards genetic testing revisited: comparing opinions between 2002 and 2010. Eur J Hum Genet 21, 793799.CrossRefGoogle ScholarPubMed
77. Jonassaint, CR, Santos, ER, Glover, CM et al. (2010) Regional differences in awareness and attitudes regarding genetic testing for disease risk and ancestry. Hum Genet 128, 249260.CrossRefGoogle ScholarPubMed
78. Goddard, KAB, Moore, C, Ottman, D et al. (2007) Awareness and use of direct-to-consumer nutrigenomic tests, United States, 2006. Genet Med 9, 510517.CrossRefGoogle Scholar
79. Hughes, C, Gomez-Caminero, A, Benkendorf, J et al. (1997) Ethnic differences in knowledge and attitudes about BRCA1 testing in women at increased risk. Patient Educ Couns 32, 5162.CrossRefGoogle ScholarPubMed
80. Gibney, MJ & Walsh, MC (2013) The future direction of personalised nutrition: my diet, my phenotype, my genes. P Nutr Soc 72, 219225.CrossRefGoogle ScholarPubMed
81. Morin, K (2009) Knowledge and attitudes of Canadian consumers and health care professionals regarding nutritional genomics. OMICS A J Integr Biol 13, 3741.CrossRefGoogle ScholarPubMed
82. Stewart-Knox, BJ, Bunting, BP, Gilpin, S et al. (2009) Attitudes toward genetic testing and personalised nutrition in a representative sample of European consumers. Br J Nutr 101, 982989.CrossRefGoogle Scholar
83. Roosen, J, Bruhn, M, Mecking, R et al. (2008) Consumer demand for personalized nutrition and functional food. Int J Vitam Nutr Res 78, 269274.Google ScholarPubMed
84. Ronteltap, A, van Trijp, JCM & Renes, RJ (2009) Consumer acceptance of nutrigenomics-based personalised nutrition. Br J Nutr 101, 132144.CrossRefGoogle ScholarPubMed
85. Stewart-Knox, B, Kuznesof, S, Robinson, J et al. (2013) Factors influencing European consumer uptake of personalised nutrition. Results of a qualitative analysis. Appetite 66, 6774.CrossRefGoogle ScholarPubMed
86. Poínhos, R, van der Lans, IA, Rankin, A et al. (in press) Psychological determinants of consumer acceptance of personalised nutrition in 9 European countries. PLoS ONE (In the Press).Google Scholar
87. Maddux, JE, Rogers, RW (1983) Protection motivation and self-efficacy: a revised theory of fear appeals and attitude change. J Exp Soc Psychiatry 19, 469479.CrossRefGoogle Scholar
88. Rogers, RW (1975) A protection motivation theory of fear appeals and attitude change 1. J Psychol 91, 93114.CrossRefGoogle Scholar
89. Floyd, DL, Prentice-Dunn, S, Rogers, RW (2000) A meta-analysis of research on protection motivation theory. J Appl Soc Psychol 30, 407429.CrossRefGoogle Scholar
90. Ahlgren, J, Nordgren, A, Perrudin, M et al. (2013) Consumers on the internet: ethical and legal aspects of commercialisation of personalized nutrition. Genes Nutr 8, 349355.CrossRefGoogle Scholar
91. Bollinger, JM, Green, RC & Kaufman, D (2013) Attitudes about regulation among direct-to-consumer genetic testing customers. Genet Test Mol Bioma 17, 424428.CrossRefGoogle ScholarPubMed