Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-25T05:17:57.478Z Has data issue: false hasContentIssue false

Overcoming the obstacles to returning genomic research results

Published online by Cambridge University Press:  17 April 2013

MICHAEL LEE Jr.
Affiliation:
Rare Genomics Institute, Missouri, USA
JIMMY CHENG-HO LIN*
Affiliation:
Rare Genomics Institute, Missouri, USA
*
*Corresponding author: Rare Genomics Institute, Missouri, USA. e-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Type
Commentary
Copyright
Copyright © Cambridge University Press 2013 

On 11 October, 2012, the Presidential Commission for the Study of Bioethical Issues released a report concerning whole-genome sequencing and privacy (Presidential Commission for the Study of Bioethical Issues, 2012). The Commission's report, Privacy and Progress in Whole Genome Sequencing, correctly emphasizes that individual privacy must be respected – but we suggest that there remains one way in which genetic information is currently kept too private. As described in Science Translational Medicine in July (Hunter et al., Reference Hunter, Hopfer, Terry and Coors2012), our status quo often requires researchers to withhold genetic information not only from third parties such as insurers or employers, but also sometimes from patients and subjects themselves. A variety of obstacles prevent physicians and scientists from utilizing our most powerful technological advancements to benefit those very individuals who have trusted us with their bodies and their care.

As Dr Gholson Lyon reports heartbreakingly (Lyon, Reference Lyon2012), in 2009, he discovered the genes responsible for a devastating congenital illness – an aged appearance, facial abnormalities and developmental delay – and published a scientific manuscript in 2011 (Rope et al., Reference Rope, Wang, Evjenth, Xing, Johnston, Swensen, Johnson, Moore, Huff, Bird, Carey, Opitz, Stevens, Jiang, Schank, Fain, Robison, Dalley, Chin, South, Pysher, Jorde, Hakonarson, Lillehaug, Biesecker, Yandell, Arnesen and Lyon2011). However, when one of his subjects asked him what he knew, he was forced to withhold his knowledge because his results were generated in a research laboratory and not a clinical one. These family members – the very ones who had the most at stake – were excluded from the discussion.

Sometimes that heartbreak is unavoidable. In particular, there are four major obstacles to returning genomic findings to research subjects and their families. First, sometimes it is logistically impossible. Second, sometimes the results are too unreliable to be responsibly shared. Third, some commentators argue that results should be shared only when a medical therapy is available. Fourth, sometimes privacy concerns or previously signed informed consents prohibit the return of findings.

We argue here that we must begin the reforms needed to overcome these four obstacles. The research community drafted informed consents, structured research laboratories, and wrote ethical guidelines about harms and benefits in the pre-genomic era. This often places genomics researchers in difficult situations in which they must choose between their research protocols and the well-being of their patients. The New York Times, among others, has reported several of these scenarios. One anonymous subject could not be told that he had HIV because no identification was kept with the samples, depriving him of an early start against his illness. Another research group found that 5% of colon cancers in a sample might respond to a medication called trastuzumab, but the protocol prohibited relaying that information to the participants and so that promising treatment will never be tried. In another case, a woman was planning on a prophylactic mastectomy, when researchers found that she did not in fact have the gene she feared predisposed her to breast cancer. They were barred by the study protocol from informing her, but fortunately in that case her institution's ethics committee intervened at the last minute. In contrast, a family being studied at another institution did carry the predisposing gene, but was never informed due to ethical concerns. They will find out only when the first diagnoses of breast cancer begin to occur in their mothers and daughters (Kolata, Reference Kolata2012).

Before genomics, research was often incapable of yielding helpful personal information. There was no benefit to returning results, and so the value of non-maleficence trumped beneficence and autonomy. After all, no beneficial options to return information were truly available and thus no meaningful choices existed for individuals to make. Thus, informed consents were drafted and information repositories were built on anonymity to protect privacy (Ries et al., Reference Ries, LeGrandeur and Caulfield2010). Anonymous samples could not influence individual medical decisions (Cho, Reference Cho2008), and so the careful controls used in clinical laboratories were reasonably deemed unnecessary in research projects. However, we now live in an era with options, and those options properly belong to the autonomy of those who have the most at stake.

Some commentators argue that researchers have an obligation to return results to participants (Knoppers et al., Reference Knoppers, Joly, Simard and Durocher2006) while others continue to maintain a non-disclosure position (Dressler, Reference Dressler2009); sometimes major working groups are unable to reach even internal consensus (Fabsitz et al., Reference Fabsitz, McGuire, Sharp, Puggal, Beskow, Biesecker, Bookman, Burke, Burchard, Church, Clayton, Eckfeldt, Fernandez, Fisher, Fullerton, Gabriel, Gachupin, James, Jarvik, Kittles, Leib, O'Donnell, O'Rourke, Rodriguez, Schully, Shuldiner, Sze, Thakuria, Wolf and Burke2010). Legitimate barriers remain, but we must place a priority on returning research results and even incidental findings, and we must commit to surmounting the four key obstacles to doing so. Below, we address each obstacle in turn, and describe ways in which the research community might overcome them.

1. Logistics

Many projects study a large number of subjects, and the range of potential findings in sequencing is nearly limitless (Cassa et al., Reference Cassa, Savage, Taylor, Green, McGuire and Mandl2012). Often, searching for all known incidental findings and reporting them to participants will simply be impossible. However, many studies such as Dr Lyon's, are smaller, seeking out one genetic defect in a family with an obviously genetic but a yet undescribed syndrome (Lyon et al., Reference Lyon, Jiang, Van Wijk, Wang, Bodily, Xing, Tian, Robison, Clement, Lin, Zhang, Liu, Moore, Glessner, Elia, Reimherr, van Solinge, Yandell, Hakonarson, Wang, Johnson, Wei and Wang2011). Returning findings to patients in small studies such as these would face minimal logistical barriers.

Even in larger studies, returning information may soon be logistically possible. Bioinformatics and information technology continue to proliferate, making search and communication easier. For example, large-scale genomics data repositories (‘biobanks’) already make it possible for multiple groups to study one genome in pursuit of varying projects, existing largely for the purpose of facilitating ‘ancillary’ research projects (Wolf et al., Reference Wolf, Crock, Van Ness, Lawrenz, Kahn, Beskow, Cho, Christman, Green, Hall, Illes, Keane, Knoppers, Koenig, Kohane, Leroy, Maschke, McGeveran, Ossorio, Parker, Petersen, Richardson, Scott, Terry, Wilfond and Wolf2012). Such biobanks could also include notification features, alerting researchers and physicians when clinically important findings were discovered.

Alternatively, one intriguing proposal suggests a ‘cryptographic method’ of keeping patient data confidential, in which each of several parties has a ‘piece’ of identifying information, and all pieces must be combined to share results with participants (Hunter et al., Reference Hunter, Hopfer, Terry and Coors2012). This promising technique would combine the best of both worlds in preserving confidentiality while still keeping patients and their physicians – each of whom would likely hold a ‘piece’ – informed, so that they could make the best decisions for their health.

Most excitingly, participant-centric initiatives (‘PCIs’) use a variety of communications technology such as social media to create a ‘user-centric’ approach, providing an ongoing, interactive method for obtaining consent and maintaining communication among participants and between participants, physicians and researchers (Kaye et al., Reference Kaye, Curren, Anderson, Edwards, Fullerton, Kanellopoulou, Lund, MacArthur, Mascalzoni, Shepherd, Taylor, Terry and Winter2012). These programmes vary considerably in their size and structure, and each would have to provide information to patient-subjects and their physicians in a slightly different way. However, this is precisely the point: adaptability allows the research sector to develop different tools, comparing them via the academic literature and accommodating the specific needs of their study's particular patient-subject population.

Furthermore, if harnessed correctly, each of these innovations could also help physicians and researchers share data quickly across research institutions. This would allow us to compare and thus better understand genomic trends among patients who share a certain phenotype – the very essence of modern genomics research (Editorial, 2012). There are currently almost no means of sharing such data (Editorial, 2012).

Modern communications technology has lowered logistical barriers in numerous other sectors, greatly facilitating the free flow of information. Such technology can also enable research to be shared from researchers to participants while still preserving privacy options. We strongly encourage genomics researchers to capitalize upon these tools.

2. Ensuring reliability

No data are ever fully reliable, but research findings are rarely subject to clinical-level regulation (Lyon, Reference Lyon2012). Most American research labs were not built to meet the requirements specified by the Clinical Laboratory Improvement Amendments (‘CLIA’), and so in this country medically significant findings cannot be relayed to subjects suffering from illness or probable future illness. Ideally, subjects could be thoroughly informed and empowered even about radically uncertain findings. Just as physicians currently warn patients that no single laboratory test is fully reliable, so research subjects could be educated of the uncertainty in their data (Lindpainter, Reference Lindpainter2012) – especially in cases where research projects are highly exploratory and uncertain. This would allow them to plan their future and make their choices with the fullest knowledge possible.

We recognize, however, that this idealized vision will be difficult to execute in many situations (Ravitsky & Wilfond, Reference Ravitsky and Wilfond2006), and that many research institutions will therefore require that findings be subjected to clinical-level rigor before being disclosed to families. A second possibility is for researchers to coordinate partnerships with clinical laboratories (Lindpainter, Reference Lindpainter2012). This approach has had success where researchers have found genetic data pointing to a molecular deficiency, such as serotonin (Chan, Reference Chan2012), that can be easily tested in a clinical laboratory. It is also possible for new tests to be devised and certified (Lyon, Reference Lyon2012), although that process is painstaking and slow.

Dr Lyon suggests a third approach (Lyon, Reference Lyon2012): that the rigor of clinical laboratories be applied to research laboratories as well, particularly in small, family-centred studies. This is not a trivial task. It would require a formal protocol to decrease the odds of mistakes, probably including the use of technology such as bar codes, external verification of reagents used and accountability for any errors (Lyon, Reference Lyon2012). However, it also presents advantages. It would require fewer parties such as insurance companies or outside physicians; clinical-standard research labs can provide answers in a timely fashion from the researcher who best understands the implications of the data. Intriguingly, a recent proposal from the United States Department of Health and Human Services (‘HHS’) suggests that patients may soon have the right to obtain results directly from CLIA-certified laboratories (Letter from Genetics Alliance to the Honourable Kathleen Sebelius, 2012). This would greatly further the transparency and openness we advocate for patient-subjects.

These increased standards will not always be logistically or financially possible (Lindpainter, Reference Lindpainter2012) – but large research centres that accompany hospitals are often affiliated with CLIA-certified labs anyway. They should consider expanding those laboratories to make them available to human researchers – especially as whole-genome sequencing makes its way into clinical medicine (Kingsmore & Saunders, Reference Kingsmore and Saunders2011; Gahl, Reference Gahl2012; Saunders et al., Reference Saunders, Miller, Soden, Dinwiddie, Noll, Alnadi, Andraws, Patterson, Krivohlavek, Fellis, Humphray, Saffrey, Kingsbury, Weir, Betley, Grocock, Margulies, Farrow, Artman, Safina, Petrikin, Hall and Kingsmore2012). And researchers should, wherever financially possible, capitalize on those resources. The status quo catches patient-subjects between reliable but obsolete testing on the one hand and cutting-edge but unverified testing on the other hand. By merging the two, we can provide better care and, also, more reliable science.

3. Actionability

Organizations that have previously considered the issue of relaying genetic findings have placed great emphasis on the availability of medical treatment or cure for any findings. For example, the Public Population Project in Genomics and Society (‘P3G’) emphasizes that researchers should consider returning findings to participants if those findings are analytically valid, reveal significant risk of a serious health condition, and are actionable – defined as having a recognized therapeutic or preventive intervention or other action with the potential to change the clinical course of a disease or condition (Knoppers et al., Reference Knoppers, Deschênes, Zawati and Tassé2013). This is understandable; informing a patient of a predisposition towards a medically unactionable disease such as Alzheimer's, for example, may distress patients without providing any meaningful way to alter the course of their disease.

Nonetheless, we believe that the emphasis on medical actionability is misplaced. Physicians do not withhold prognostic information in other medical contexts. Magnetic resonance imaging scans can help families understand the severity of a child's neurological injury after a hypoxic-ischaemic event (McKinstry et al., Reference McKinstry, Miller, Snyder, Mathur, Schefft, Almli, Shimony, Shiran and Neil2002), cancer genotyping can point towards a more or less aggressive disease, and genetic counselling can help determine whether parents are carriers of recessive genes. Each of those tests help patients and families to make crucial financial or other life decisions. Genetic testing is no different – as just one example, returning results would allow families to work with genetic counsellors as they decide whether, or how many, or when, to have children (Hens et al., Reference Hens, Nys, Cassiman and Dierickx2011). In fact, referral to professional, clinically trained genetic counsellors whenever possible can help mitigate any harm from disclosure as they help families to make decisions regarding their future.

Delivering research findings does not even require any additional testing. It requires only that we share the results of tests already performed with the individuals most affected by them.

A working group on the subject of ‘biobanks’ suggested as a guideline that researchers and biobanks may return results even in some situations where no medical treatment is available (Wolf et al., Reference Wolf, Crock, Van Ness, Lawrenz, Kahn, Beskow, Cho, Christman, Green, Hall, Illes, Keane, Knoppers, Koenig, Kohane, Leroy, Maschke, McGeveran, Ossorio, Parker, Petersen, Richardson, Scott, Terry, Wilfond and Wolf2012). We take this recommendation one step further: in our view, these are properly decisions for patient-subjects to make, not their researchers and certainly not the aggregated bodies which regulate researchers en masse.

There are real concerns to delivering unactionable results, but participants themselves strongly urge us not to shield them from knowledge which we would deem distressing: 90% of surveyed participants would want to know all their individual results, even when entirely unactionable, and 75% state that they would be less likely to participate in research which withheld findings (Kohane & Taylor, Reference Kohane and Taylor2010). This latter figure suggests that there are societal implications to withholding information even beyond the impact on patient-subjects themselves.

Accordingly, informed consents should be modified to offer options: patients could choose to be told only of findings which are medically actionable, or of any findings which offer a prognostic value and which therefore might be actionable in a broader sense.

Beyond this debate, however, we wish to emphasize that many findings from research laboratories do, in fact, have clear, immediate clinical utility (Hunter et al., Reference Hunter, Hopfer, Terry and Coors2012). Under those circumstances it is important for researchers to overcome the other obstacles to relaying information to patients.

In short: sometimes we will not be able to share data with subjects. Perhaps, it will be logistically impossible to return results, or prohibitively expensive to study the specimens in accordance with CLIA standards, or the binding laws in that laboratory's jurisdiction. And sometimes the research will be highly exploratory in nature or findings may be too uncertain to share (Miller et al., Reference Miller, Hayeems and Bytautas2010). However, there will be times – there are already times – when all these standards can easily be met, and in those situations it is unconscionable to hide known information from research subjects after they have submitted to study for the benefit of others. We must ensure that the last barrier, the manner in which we draft our informed consent agreements, does not stand in the way when other factors permit.

4. Privacy and informed consent

The Presidential Commission properly stresses the importance of informed consent and privacy and recommends that the Office for Human Research Protection (OHRP) institute minimum requirements for such documents (Presidential Commission for the Study of Bioethical Issues, 2012). These protections are indeed absolutely critical (Trinidad et al., Reference Trinidad, Fullerton, Ludman, Jarvik, Larson and Burke2011). Further, we strongly urge that OHRP permit researchers to disclose findings to research participants. This will not only permit crucial clinical decisions to be made, but will also give subjects a greater degree of ownership in the studies themselves, a critical feature of past breaches of trust (Miller et al., Reference Miller, Hayeems and Bytautas2010).

Many informed consent documents, based on agreements drafted in the pre-genomics era, prohibit researchers from contacting patients or family members with potentially relevant information (Cho, Reference Cho2008). Informed consents that keep data entirely anonymous and which prevent re-contact with subjects are of questionable effectiveness anyway (McGuire & Gibbs, Reference McGuire and Gibbs2006; Ohm, Reference Ohm2010), especially when it comes to whole-genome sequencing (Homer et al., Reference Homer, Szelinger, Redman, Duggan, Tembe, Muehling, Pearson, Stephan, Nelson and Craig2008; Jacobs et al., Reference Jacobs, Yeager, Wacholder, Craig, Kraft, Hunter, Paschal, Manolio, Tucker, Hoover, Thomas, Chanock and Chatterjee2009). Regardless, anonymity comes at too high a cost. In our efforts to keep private information from falling into the hands of third parties, we destroy it entirely or hide it even from subjects themselves. We can protect privacy without hiding information from research subjects themselves, and the cryptographic approach cited above (Hunter et al., Reference Hunter, Hopfer, Terry and Coors2012) serves as just one means by which we could accomplish that. We recognize that this will be a significant cultural shift compared with past research efforts. Nonetheless, when returning results are logistically possible, when those results are clinically reliable and when the results would be actionable in some way, we must draft informed consent documents to allow individuals access to their research findings.

Informed consents must, of course, continue to stress privacy, and clinically relevant patient and research information will continue to be subject to the protections of both the Health Insurance Privacy and Accountability Act (‘HIPAA’) (1996) and the Genetic Information Nondiscrimination Act (‘GINA’) (2008). The Presidential Commission rightly recommends that all genetic information – for example, samples obtained by a third party from a coffee cup – be subject to the same laws. However, research participants themselves should have as much access as we can reasonably grant them. The Commission worries reasonably that privacy concerns may deter individuals from participating, but we can preserve privacy while allowing subjects themselves to benefit, thus encouraging individuals to proactively seek out such research projects (Hens et al., Reference Hens, Nys, Cassiman and Dierickx2011; Terry & Terry, Reference Terry and Terry2011).

Above all, we must provide subjects with choices. They should be given the option of retaining our current, standard privacy protections: anonymous samples and/or prevention of re-contact (Hunter et al., Reference Hunter, Hopfer, Terry and Coors2012; Kolata, Reference Kolata2012; Lyon, Reference Lyon2012). However, these should merely be options, and we suspect that few patients would choose them. A 2002 phone survey suggested that 89% of respondents would want to be informed of results even when clinical significance was unclear (Wendler & Emanuel, Reference Wendler and Emanuel2002). In addition, subjects may wish that their family be notified, or not (Offit et al., Reference Offit, Groeger, Turner, Wadsworth and Weiser2004); and that they be informed even if no medical treatment is available, or not. The Presidential Commission suggests that subjects should be told whether or not incidental findings will be disclosed; we recommend further that they should be given the option if at all possible. These options would complicate informed consent documents, but the autonomy which they grant patients outweighs that marginal increase in complexity.

For legal reasons, findings from past and current studies ought to remain bound by the informed consents that subjects have signed. In some severe situations – medical exigency, or with permission of ethics boards (Kolata, Reference Kolata2012) – such agreements may be overruled, but in general existing agreements must be honoured, no matter how heartbreaking. This emphasizes the urgency of our much-needed cultural shift: we must begin drafting and implementing new informed consents immediately in order to prevent subjects and researchers from being placed in such situations in the future.

Sequencing promises the ability to unravel many of the puzzles that lie at the heart of modern medicine: why certain medications work in some individuals but not others; how some diseases originate; what we can expect in our own future. These are crucial benefits, and they hold great promise for our world at large, and especially for our future. Yet, too often, subjects themselves are kept in the dark.

In its 12th and final recommendation, the Presidential Commission rightly stresses that the benefits of whole-genome sequencing should accrue to as large a segment of society as possible. We agree fully – but we urge the Commission and researchers worldwide to go one step further: to include the very individuals who have contributed their very selves in pursuit of this research, and who have the most at stake in its success.

References

Cassa, C. A., Savage, S. K., Taylor, P. L., Green, R. C., McGuire, A. L. & Mandl, K. D. (2012). Disclosing pathogenic genetic variants to research participants: quantifying an emerging ethical responsibility. Genome Research 22, 421428.Google Scholar
Chan, C. (2012) North County Twins Cured After Whole Genome Sequencing. NBC San Diego, 25 August 2012. http://www.nbcsandiego.com/news/health/North-County-Twins-Cured-After-Whole-Genome-Sequencing-167426045.htmlGoogle Scholar
Cho, M. K. (2008). Understanding incidental findings in the context of genetics and genomics. Journal of Law, Medicine and Ethics 36, 280285, 212.Google Scholar
Clinical Laboratory Improvement Amendments, 42 CFR, §493.Google Scholar
Dressler, L. G. (2009). Disclosure of research results from cancer genomic studies: state of the science. Clinical Cancer Research 15, 42704276.Google Scholar
Editorial (2012). Share alike. Nature 490, 143144.Google Scholar
Fabsitz, R. R., McGuire, A., Sharp, R. R., Puggal, M., Beskow, L. M., Biesecker, L. G., Bookman, E., Burke, W., Burchard, E. G., Church, G., Clayton, E. W., Eckfeldt, J. H., Fernandez, C. V., Fisher, R., Fullerton, S. M., Gabriel, S., Gachupin, F., James, C., Jarvik, G. P., Kittles, R., Leib, J. R., O'Donnell, C., O'Rourke, P. P., Rodriguez, L. L., Schully, S. D., Shuldiner, A. R., Sze, R. K., Thakuria, J. V., Wolf, S. M. & Burke, G. L. (2010). National heart, lung, and blood institute working group, ethical and practical guidelines for reporting genetic research results to study participants: updated guidelines from a national heart, lung, and blood institute working group. Circulation Cardiovascular Genetics 3, 574580.Google Scholar
Gahl, W. A. (2012). The battlefield of rare diseases: where uncommon insights are common. Science Translational Medicine 4, 154ed7.CrossRefGoogle ScholarPubMed
Genetic Information Nondiscrimination Act (2008). Public Law 110–233, 122 Stat. 881.Google Scholar
Health Insurance Privacy and Accountability Act (1996). Public Law No. 104–191, 110 Stat. 1936.Google Scholar
Hens, K., Nys, H., Cassiman, J. J. & Dierickx, K. (2011). The return of individual research findings in paediatric genetic research. Journal of Medical Ethics 37, 179183.Google Scholar
Homer, N., Szelinger, S., Redman, M., Duggan, D., Tembe, W., Muehling, J., Pearson, J. V., Stephan, D. A., Nelson, S. F. & Craig, D. W. (2008). Resolving individuals contributing trace amounts of DNA to highly complex mixtures using high-density SNP genotyping microarrays. PLoS Genetics 4, e1000167.Google Scholar
Hunter, L. E., Hopfer, C., Terry, S. F. & Coors, M. E. (2012). Reporting actionable research results: shared secrets can save lives. Science Translational Medicine 4, 143cm8.Google Scholar
Jacobs, K. B., Yeager, M., Wacholder, S., Craig, D., Kraft, P., Hunter, D. J., Paschal, J., Manolio, T. A., Tucker, M., Hoover, R. N., Thomas, G. D., Chanock, S. J. & Chatterjee, N. (2009). A new statistic and its power to infer membership in a genome-wide association study using genotype frequencies. Nature Genetics 41, 12531257.Google Scholar
Kaye, J., Curren, L., Anderson, N., Edwards, K., Fullerton, S. M., Kanellopoulou, N., Lund, D., MacArthur, D. G., Mascalzoni, D., Shepherd, J., Taylor, P. L., Terry, S. F. & Winter, S. F. (2012). From patients to partners: participant-centric initiatives in biomedical research. Nature Reviews Genetics 13, 371376.CrossRefGoogle ScholarPubMed
Kingsmore, S. F. & Saunders, C. J. (2011). Deep sequencing of patient genomes for disease diagnosis: when will it become routine? Science Translational Medicine 3, 87ps23.Google Scholar
Knoppers, B. M., Joly, Y., Simard, J. & Durocher, F. (2006). The emergence of an ethical duty to disclose genetic research results: international perspectives. European Journal of Human Genetics 14, 11701178.Google Scholar
Knoppers, B. M., Deschênes, M., Zawati, M. H. & Tassé, A. M. (2013). Population studies: return of research results and incidental findings policy statement. European Journal of Human Genetics 21, 245247.Google Scholar
Kohane, I. S. & Taylor, P. L. (2010). Multidimensional results reporting to participants in genomic studies: getting it right. Science Translational Medicine 2, 37cm19.Google Scholar
Kolata, G. (2012) Genes Now Tell Doctors Secrets They Can't Utter, N. Y. Times, 25 August 2012. http://www.nytimes.com/2012/08/26/health/research/with-rise-of-gene-sequencing-ethical-puzzles.htmlGoogle Scholar
Letter from Genetics Alliance to the Honorable Kathleen Sebelius et al. (2012) A Consensus Letter to the HHS Office of Civil Rights and the Centers for Medicare and Medicaid Services on the Need to Finalize the Proposed Rule to Expand the Rights of Patients to Access their Test Results, 18 October 2012. http://www.geneticalliance.org/sites/default/files/ksc_assets/pdfs/clia_consensus_letter1012%202012.pdfGoogle Scholar
Lindpainter, K. (2012). Genetics research: clinical standards not practical in the lab. Nature 483, 158.CrossRefGoogle Scholar
Lyon, G. J. (2012). Personalized medicine: bring clinical standards to human-genetics research. Nature 482, 300301.CrossRefGoogle ScholarPubMed
Lyon, G. J., Jiang, T., Van Wijk, R., Wang, W., Bodily, P. M., Xing, J., Tian, L., Robison, R. J., Clement, M., Lin, Y., Zhang, P., Liu, Y., Moore, B., Glessner, J. T., Elia, J., Reimherr, F., van Solinge, W. W., Yandell, M., Hakonarson, H., Wang, J., Johnson, W. E., Wei, Z. & Wang, K. (2011). Exome sequencing and unrelated findings in the context of complex disease research: ethical and clinical implications. Discovery Medicine 12, 4155.Google Scholar
McGuire, A. L. & Gibbs, R. A. (2006). Genetics: no longer de-identified. Science 312, 370371.Google Scholar
McKinstry, R. C., Miller, J. H., Snyder, A. Z., Mathur, A., Schefft, G. L., Almli, C. R., Shimony, J. S., Shiran, S. I. & Neil, J. J. J. (2002). A prospective longitudinal diffusion tensor imaging study of brain injury in newborns. Neurology 59, 825827.Google Scholar
Miller, F. A., Hayeems, R. Z. & Bytautas, J. P. (2010). What is a meaningful result? Disclosing the results of genomic research in autism to research participants. European Journal of Human Genetics 18, 867871.Google Scholar
Offit, K., Groeger, E., Turner, S., Wadsworth, E. A. & Weiser, M. A. (2004). The ‘duty to warn’ a patient's family members about hereditary disease risks. JAMA, Journal of American Medical Association 292, 14691473.CrossRefGoogle ScholarPubMed
Ohm, P. (2010). Broken promises of privacy: responding to the surprising failure of anonymization. UCLA Law Review 57, 17011777.Google Scholar
Presidential Commission for the Study of Bioethical Issues, Privacy and Progress in Whole Genome Sequencing, October 2012. http://www.bioethics.gov/cms/sites/default/files/Privacy-and-Progress_PCSBI_1012.pdfGoogle Scholar
Ravitsky, V. & Wilfond, B. S. (2006). Disclosing individual genetic results to research participants. American Journal of Bioethics 6, 817.Google Scholar
Ries, N. M., LeGrandeur, J. & Caulfield, T. (2010). Handling ethical, legal and social issues in birth cohort studies involving genetic research: Responses from studies in six countries. BMC Medical Ethics 11, 4.Google Scholar
Rope, A. F., Wang, K., Evjenth, R., Xing, J., Johnston, J. J., Swensen, J. J., Johnson, W. E., Moore, B., Huff, C. D., Bird, L. M., Carey, J. C., Opitz, J. M., Stevens, C. A., Jiang, T., Schank, C., Fain, H. D., Robison, R., Dalley, B., Chin, S., South, S. T., Pysher, T. J., Jorde, L. B., Hakonarson, H., Lillehaug, J. R., Biesecker, L. G., Yandell, M., Arnesen, T. & Lyon, G. J. (2011). Using VAAST to identify an x-linked disorder resulting in lethality in male infants due to N-terminal acetyltransferase deficiency. American Journal of Human Genetics 89, 2843.Google Scholar
Saunders, C. J., Miller, N. A., Soden, S. E., Dinwiddie, D. L., Noll, A., Alnadi, N. A., Andraws, N., Patterson, M. L., Krivohlavek, L. A., Fellis, J., Humphray, S., Saffrey, P., Kingsbury, Z., Weir, J. C., Betley, J., Grocock, R. J., Margulies, E. H., Farrow, E. G., Artman, M., Safina, N. P., Petrikin, J. E., Hall, K. P. & Kingsmore, S. F. (2012). Rapid whole-genome sequencing for genetic disease diagnosis in neonatal intensive care units. Science Translational Medicine 4, 154ra135.CrossRefGoogle ScholarPubMed
Terry, S. F. & Terry, P. F. (2011). Power to the people: participant ownership of clinical trial data. Science Translational Medicine 3, 69cm3.Google Scholar
Trinidad, S. B., Fullerton, S. M., Ludman, E. J., Jarvik, G. P., Larson, E. B. & Burke, W. (2011). Research ethics. Research practice and participant preferences: the growing gulf. Science 331, 287288.Google Scholar
Wendler, D. & Emanuel, E. (2002). The debate over research on stored biological samples: what do sources think? Archives of Internal Medicine 162, 14571462.Google Scholar
Wolf, S. M., Crock, B. N., Van Ness, B., Lawrenz, F., Kahn, J. P., Beskow, L. M., Cho, M. K., Christman, M. F., Green, R. C., Hall, R., Illes, J., Keane, M., Knoppers, B. M., Koenig, B. A., Kohane, I. S., Leroy, B., Maschke, K. J., McGeveran, W., Ossorio, P., Parker, L. S., Petersen, G. M., Richardson, H. S., Scott, J. A., Terry, S. F., Wilfond, B. S. & Wolf, W. A. (2012). Managing incidental findings and research results in genomic research involving biobanks and archived data sets. Genetics in Medicine 14, 361384.Google Scholar