Towards a more representative morphology: clinical and ethical considerations for including diverse populations in


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© American College of Medical Genetics and Genomics Review

An important gap exists in the screening toolkit used by 
physicians and other health-care professionals to help diag-
nose genetic syndromes in their patients via the observa-
tion of phenotypic characteristics. Visual diagnosis relies on 
textbooks of dysmorphology, which include images of indi-
viduals with classic phenotypes for a wide range of genetic 
diseases. These morphological atlases have been a standard 
diagnostic tool for clinical geneticists for decades and guide 
clinicians in their choice of molecular testing.1–4  In the most 
widely used of these diagnostic atlases, the majority of the 
images are of individuals of northern European descent, 
reflecting the patient populations for whom the clinicians 
who developed these texts originally provided clinical care. 
However, because many of the genetic conditions profiled 
in these texts are prevalent in populations across the world, 
it is now clear that these texts do not sufficiently reflect 
global ancestral diversity. The lack of a variety of phenotypic 
images in available atlases potentially limits the utility of 
these atlases as diagnostic tools in globally diverse popula-
tions, causing geneticists difficulty in properly diagnosing 
conditions in individuals of different ancestral backgrounds 
who may present with variable morphological features.

Even the relatively simple diagnosis of Down syndrome in 
diverse populations is not straightforward, as seen in Figure 1, 
which includes photographs of children with Down syndrome 
from understudied populations. The observer’s gestalt conclu-
sion upon examining these photos may not be the diagno-
sis of Down syndrome, because the eye and nose differences 
that occur in various ethnicities mask the “textbook” features 
described in most medical texts. For example, a feature of 
Down syndrome is epicanthal folds at the inner portion of the 
eye; however, this is a normal finding in individuals of Asian 
descent. This difficulty with diagnosis is not unique to coun-
tries with diverse racial and ethnic populations; diagnosis can 
be challenging even in locations with relatively homogeneous 
populations if this majority is of non-European ancestral ori-
gin. Skilled local clinicians working in these areas may still 
struggle to identify genetic syndromes by phenotype, because 
the available training tools and classical phenotype images of 
particular disorders predominantly feature individuals with 
European ancestry.

Proposals to address the underinclusion of images of human 
malformation syndromes from diverse populations in existing 
morphological atlases, such as the one described by Muenke and 

Submitted 22 July 2015; accepted 6 January 2016; advance online publication 10 March 2016. doi:10.1038/gim.2016.7

An important gap exists in textbooks (or atlases) of dysmorphol-
ogy used by health-care professionals to help diagnose genetic syn-
dromes. The lack of varied phenotypic images in available atlases 
limits the utility of these atlases as diagnostic tools in globally 
diverse populations, causing geneticists difficulty in diagnosing 
conditions in individuals of different ancestral backgrounds who 
may present with variable morphological features. Proposals to 
address the underinclusion of images from diverse populations in 
existing atlases can take advantage of the Internet and digital pho-
tography to create new resources that take into account the broad 
global diversity of populations affected by genetic disease. Creating 
atlases that are more representative of the global population will 
expand resources available to care for diverse patients with these 

conditions, many of whom have been historically underserved 
by the medical system. However, such projects also raise ethical 
questions that are grounded in the complex intersection of imag-
ery, medicine, history, and race and ethnicity. We consider here 
the benefits of producing such a resource while also considering 
ethical and practical concerns, and we offer recommendations for 
the ethical creation, structure, equitable use, and maintenance of a 
diverse morphological atlas for clinical diagnosis.

Genet Med advance online publication 10 March 2016

Key Words: ethics; dysmorphology; genetics; global health; diverse 
populations 

1Department of Bioethics, Clinical Center, National Institutes of Health, Bethesda, Maryland, USA; 2Social and Behavioral Research Branch, National Human Genome Research 
Institute, National Institutes of Health, Bethesda, Maryland, USA; 3Bioethics Core, National Human Genome Research Institute, National Institutes of Health, Bethesda, Maryland, 
USA; 4Medical Genetics Branch, National Human Genome Research Institute, National Institutes of Health, Bethesda, Maryland, USA; 5Center for Research on Genomics and Global 
Health, National Human Genome Research Institute, National Institutes of Health, Bethesda, Maryland, USA.Correspondence: Sara Chandros Hull (shull@mail.nih.gov) 

Towards a more representative morphology: clinical and 
ethical considerations for including diverse populations in 

diagnostic genetic atlases

Maya Koretzky,1 Vence L. Bonham,2 Benjamin E. Berkman,1,3 Paul Kruszka,4  
Adebowale Adeyemo,5 Maximilian Muenke4 and Sara Chandros Hull1,3

GeneTics in medicine  |  Volume 18  |  Number 11  |  November 2016

http://www.nature.com/doifinder/10.1038/gim.2016.7
mailto:shull@mail.nih.gov


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KORETZKY et al  |  Considerations for including diverse populations in diagnostic genetic atlasesReview

colleagues in this issue of Genetics in Medicine,5 can take advan-
tage of the ubiquity of the Internet and the ease of digital photog-
raphy to create new resources that take into account the broad 
global diversity of populations affected by genetic disease and 
can be made widely available. Creating a genetic dysmorphology 
atlas that is more representative of the global population will help 
expand the resources available to care for diverse patients with 
these conditions, many of whom have been historically under-
served in various ways by the medical system.

Birth defects are now a leading cause of childhood mortal-
ity and morbidity worldwide; however, medical geneticists are 
most commonly found in university medical centers in devel-
oped countries. Most developing countries do not have medical 
geneticists. For example, although the largest country in Africa 
is Nigeria, with more than 200 million people and the largest 
economy, several of the authors of this article (A.A., P.K., M.M.) 
travel there regularly and are aware that there are no practicing 
clinical geneticists there; our collaborators in Nigeria are pedi-
atric cardiologists. This is contrast to the Washington, DC, area, 
where there are more than 20 medical (MD) geneticists.

From a clinical perspective, more diverse atlases would 
enable more accurate and earlier syndromic diagnosis of con-
genital malformations to be made across patients of a variety of 
ancestral origins, potentially leading to improved medical care 
for persons of non-European descent with these conditions.6 

Including a wider selection of individuals in morphological 
atlases could also lay the groundwork for addressing other 
aspects of medical diagnosis and care, as well as genetic disease, 
by building relationships and research capacity in the interna-
tional arena.7 For example, allowing international physicians to 
participate in the creation of the atlas by contributing images of 
their patients can facilitate international cooperation and estab-
lish networks of clinicians and researchers in underresourced 
areas. By enabling more accurate diagnosis of individuals, the 
atlas would also enable researchers to aggregate these data and 
glean a more accurate picture of the global prevalence of cur-
rently underdiagnosed genetic diseases8 (for instance, evidence 
is emerging that cystic fibrosis is vastly underdiagnosed in pop-
ulations of non-European origin9).

However, the project also raises ethical questions about the 
selection and portrayal of individuals in the atlas and who will 
have access to this database. We consider the benefits of pro-
ducing such a resource and consider the ethical and practical 
concerns raised. We also offer recommendations for the ethical 
creation, structure, equitable use, and maintenance of a diverse 
morphological atlas for clinical diagnosis.

eTHicAL cOnsideRATiOns
The ethical and social concerns that are raised by the creation 
of a diverse morphological atlas are grounded in the complex 
intersection of imagery, medicine, history, and race and ethnic-
ity. These concerns can be sorted into two general categories: 
(i) historically rooted concerns about reifying racial and ethnic 
groups as discrete biological classifications and the misuse of 
racial and ethnic categories and (ii) contemporary consider-
ations regarding access to the database and respecting patient 
autonomy and privacy in an Internet-based environment.

There is a long and complex history of classifying people into 
groups to search for a biological basis for racial difference,10,11 
with race persistently occupying a liminal space between social 
construct and biological utility.12 The medicalization of race has 
at times been used as a way to justify discriminatory practices 
outside of the medical sphere and as a way to challenge these 
same practices and push back against them.13 This complex 
relationship between medicine and race politics has been dem-
onstrated by scholars in various contexts, from Lundy Braun’s 
classic work on differing spirometry measures for different 
races to Nancy Pollock’s scholarship on the history and anthro-
pology of how cardiac disease in African Americans has been 
articulated by the medical establishment.14 (For one example 
regarding heart disease, see ref.. 15.) In many ways, biomedicine 
continues to reify an interpretation of race as a biological qual-
ity that affects health and disease, rather than as an identity that 
is more indicative of social group and environmental influences 
than of an underlying physiology.

Although the notion of “biological race” has been misused 
by medical professionals in many instances, it is also true that 
disease and health risks facing different individuals may be 
tracked by ancestry, social experiences, and environment—
qualities for which race identification may often act as a proxy.16 

Figure 1 children with down syndrome from Thailand, india, and 
nigeria. Courtesy of Ekanem Ekure, S.J. Patil, Girisha K.M., Antonio Richieri-
Costa, and Vorasuk Shotelersuk.

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Scholars such as David Wasserman and Nancy Krieger, among 
others, have explored the benefits and pitfalls of using race cat-
egories in medicine for individual therapeutic purposes or as a 
way to talk about social groups and structural racism and their 
impact on health.17,18

This tension between the medical utility and the medical 
misuse of race categories is perhaps most salient in the field of 
genetics, a discipline in which disease risks are correlated with 
ancestry but that also has historical ties to nineteenth- and 
twentieth-century eugenics science.19 Scholars from a wide 
range of disciplines have explored the ethics, anthropology, 
and history of race and genetics. (For further reading, please 
see refs. 20–22.) The language used by geneticists may serve to 
confuse the connections that exist between race and genetics. 
Although genetic variation correlates with ancestral markers, 
race is a much more complex and largely self-identified con-
cept that cannot be determined through biomedical testing.23,24 
Although guidelines on the use of accurate terminology related 
to race categories in genetic research publications emphasize 
the importance of defining how these terms are being used in 
a given research project (e.g., as a proxy for ancestral origin or 
socioeconomic status), these guidelines are rarely followed in 
contemporary genetics publications.25

Medical geneticists have often been in the middle of race–
dysmorphology debates. Indeed, they were instrumental in 
changing one of its more explicit expressions: referring to 
children with trisomy 21 as “mongols” or as having “mongol-
oid features” in medical literature as well as in the lay press. 
This practice originated in the 1860s, when a physician noted 
physical similarities in the appearance of people with trisomy 
21 and individuals previously described as belonging to the 
“Mongoloid” race. Nearly a century later, geneticists began to 
call for discontinuing the use of the term “mongoloid” and 
its variants, opting for the term “Down syndrome” instead. 
Although the term remains in use, geneticists and professional 
organizations have formally recognized that terminology that 
connects a genetic condition associated with cognitive impair-
ment, physical features of that condition, and a country, such as 
Mongolia, is derogatory and should be discontinued.26

In addition to these important linguistic nuances, there is also 
a long history of the unjust use of morphological images of differ-
ent racial “types” by the biomedical establishment. The popula-
tions that have been left out of morphological diagnostic atlases 
are also populations that have historically been underserved or 
exploited by the medical professions. In many cases, racialized 
images played a large role in pseudoscientific research to bol-
ster claims of biological differences between races and to argue 
for the premise of inferiority of certain groups.27 For example, 
throughout the nineteenth century, the widespread creation of 
eugenicist atlases and, later, Nazi photographic databases were 
used for cataloguing and distinguishing between the races, with 
the ultimate goal of eradicating populations believed to be infe-
rior.28 Images of disabled individuals also figured prominently in 
medically sanctioned eugenics campaigns well into the twenti-
eth century in both America and Western Europe29.

Although the goals of this project are wholly different from 
these historical analogues, the very practice of organizing 
racially labeled images in a medical textbook merits careful 
scrutiny because of this long and problematic history.

We also considered concerns that have been expressed by 
contemporary disability rights advocates that by reducing an 
individual’s facial features or distinctive physiological traits to 
a set of symptoms for determining a genetic diagnosis, dys-
morphology atlases might objectify the individual being photo-
graphed and could reinforce stereotypes and stigma associated 
with these conditions. (See, for example, ref. 29.) Although 
these are important issues to consider, we decided that ade-
quate treatment of disability perspectives is beyond the scope 
of this article.

In addition there are several important practical decisions 
to work through regarding the database. For example, who 
will maintain the database and how will access be regulated? 
An open-access database would be consistent with the justice-
oriented goals of the project to expand the availability of such 
diagnostic tools around the world. However, the easy accessibil-
ity of race-labeled images and data could pose risks such as stig-
matizing a particular individual, community, or population.30 
The database could potentially be accessed to use the images or 
other material wrongfully and with malicious intent. This ten-
sion between the ideal of open-access medical knowledge and 
the practical realities of patient privacy is not speculative; simi-
lar concerns have begun to emerge for other online platforms 
for uploading, distributing, and viewing ostensibly anonymized 
patient images by medical professionals.31 However, we feel that 
the goals of this project to assist medical providers in making 
earlier and more accurate diagnoses of dysmorphic syndromes 
(both environmentally and genetically caused) will provide a 
benefit that outweighs such concerns about widespread access.

In addition to patient privacy, there are other important 
questions raised by this database at the level of individual 
participants. For example, it may be challenging to obtain the 
informed consent of individual participants to generate and use 
their images in the atlas for several reasons. Participant families 
who come from especially remote or underresourced areas may 
have difficulty understanding the scope of who will be able to 
access the images. Craniofacial defects require the inclusion of 
facial pictures for a diagnosis, which increases the risk of indi-
viduals being identified. Because many of the diseases that will 
be profiled manifest in childhood and/or are characterized by 
cognitive impairment or intellectual disability, many partici-
pants will be unable to formally consent on their own behalf, 
which raises questions about surrogate permission and whether 
it is sufficient for use of their images. Furthermore, there are 
questions about whether it will (and should) be possible for 
participants to remove their images from the database if they 
change their mind about participation in the project. These 
questions raise important concerns about autonomy and pri-
vacy for individuals who will be photographed and included in 
the database.

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RecOmmendATiOns
Taking these historical concerns and ethical questions seriously 
will require careful design and implementation decisions in the 
creation of this kind of resource (Table 1). Especially impor-
tant when considering the historical context of morphological 
atlases are questions of how ancestry will be determined for 
the purposes of this project, how it will be noted in the atlas, 
and how individuals of different ancestral backgrounds will be 
selected to participate. The goal is to strike a balance between 
providing useful data to local clinicians (for example, clinicians 
working in only one country may want to be able to narrow the 
atlas to only show patient images from that country) and avoid-
ing the reification of racial or ethnic categories. Our recom-
mendations are informed by engagement with an international 
group of advisors who are clinicians from non-Western coun-
tries, including Uganda, Nigeria, South Africa, Rwanda, Mali, 
Malaysia, India, Thailand, Japan, China, South America, and 
the Middle East. Both the necessity of new atlases and the struc-
ture of the project are grounded in challenges and complexities 
that were identified by members of this diverse group who are 
providing oversight of the website described by Muenke et al.5

We believe that the organization of newer atlases can be an 
important point of departure from the problematic historical 
examples discussed. Atlases should be structured to allow sort-
ing of images by disease or by the current country or region of 
residence of the photographed patient so that clinicians could 
search for all individuals with a particular condition (e.g., any 
patient with Williams syndrome) and/or by nation or region 
(e.g., all photographs of individuals living in Sub-Saharan 
Africa). Patients would then be given the opportunity to iden-
tify subjective ethnic, racial, and/or tribal identities that would 
appear alongside the picture of the individual in addition to 
data about the national origins of each of the subject’s four 
grandparents, but they would not be searchable variables in the 
database. For example, the photograph of a Southeast Asian 
individual with Down syndrome will appear on the screen if 
“Down syndrome” or “Southeast Asia” is searched. If the sub-
ject self-identified as Khmer and indicated that all four grand-
parents were born in Thailand, then this information will 
appear with the image of the subject as additional descriptive 

information, but it will not be possible for clinicians to search 
the database by the term “Asian,” “Khmer,” or “Thai” ancestral 
origin. Our work draws on the model of language for genetic 
variation and ancestry proposed previously.32

By organizing the searchable features of the atlas by disease 
or current nationality, and by associating self-identified ethnic/
racial/tribal identity information with the images in a non-
searchable manner, the clinical utility of the atlas as a diagnos-
tic tool across a wide range of phenotypes can be realized while 
limiting the possible unintended uses of such data for questions 
related to eugenic, scientifically misplaced, or other flawed 
research. The standard method of tracing ancestral origin via 
self-report of the nationalities of a participant’s four grand-
parents seems to be an appropriate method for morphological 
atlases as well. We acknowledge that estimating ancestral ori-
gin via one’s four grandparents may be less informative in some 
populations with significant diversity of continental ancestry, 
for example, within the United States.33 However, we emphasize 
that the goals of the new atlas are to be inclusive of populations 
from around the world, most of whom will tend not to have the 
same degree of heterogeneity of continental ancestry.

Another important way that new atlases can be distinguished 
from historical projects involving the classification of indi-
viduals by race is to include individuals from a geographically 
diverse population while avoiding the use of ethnicity-related 
criteria and language when selecting participants and catego-
rizing them for the atlas25 by selecting participants from the 
pool of individuals who arrive at participating medical centers 
around the world. The goal of the atlas is to reflect the diversity 
that is seen in clinical practice around the world rather than to 
parse the origin of patients by self-reported “race,” continental 
ancestry, or ethnic origin. Following diagnosis of a genetic dis-
ease, they will be approached about participating in the atlas 
project first, and asked for their ancestral origin data later in 
the process. No quota of individuals of different ancestral back-
grounds to be included in the atlas will be set, nor will attempts 
be made to find “pure” examples of different ancestral groups. 
Treating ancestry as data to be collected after participants are 
selected, asked for their consent, and photographed will help to 
guard against the selection of subjects who are typical (“pure” 

Table 1 Summary of recommendations for the creation of new diverse morphological databases
Appropriate use of ancestral categories/avoiding misuse of historic racial/ethnic constructs

1. Organize the atlas by disease rather than ancestral origin

2. Limit potential search parameters involving ancestral origin

3. Approach potential participants about being photographed for the atlas before asking them about their ancestral origin

4.  Avoid “race” or “ethnicity” terminology and standardized lists of options when interviewing potential participants and reporting their responses in 
the published atlas. Instead, use terms and phrases such as “ancestry,” and open-ended questions about ethnic and cultural identity such as “where 
were your grandparents born?”

Database access and maintenance

5. Seek multinational input in organizing and maintaining the atlas

6. Involve locals in designing the consent forms for each regional site

Patient autonomy and privacy

7.  Construct an interface for the database that describes its purpose, asks users to certify that their use of the resource will be consistent with its 
diagnostic intent, and does not allow for the downloading of participant images

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or “ideal”) types of any given group, thus distancing this project 
from prior eugenics-oriented image collecting practices.

Additionally, we recommend that participants should not be 
prompted to provide data regarding their ancestral origins from 
a pre-existing list of possible race or ethnic categories, such as 
the list suggested by the US Office of Management and Budget 
(https://www.whitehouse.gov/omb/fedreg_race-ethnicity). 
Additionally, these categories do not reflect how individuals 
outside the United States describe themselves. The terms con-
tained in such lists are generally insufficient for capturing the 
genetic diversity of human populations and do not accurately 
describe the goal of an atlas that aims to represent individuals 
with a wide variety of ancestral backgrounds. In making this 
recommendation, we are following the guidelines set by the 
Race, Ethnicity, and Genetics Working Group of the American 
Journal of Human Genetics.12 At best, these terms included in 
such lists are proxies for constructs that can be more accurately 
captured through other data, such as the continental origins of 
four grandparents. In addition, as described, they carry mul-
tiple connotations (social, biological, cultural), many of which 
are inaccurate or simply not relevant to this endeavor.

The question of what person, group, or organization will col-
lect and maintain the images is an important one that is tied 
to concerns about the potential exploitation of marginalized 
groups. Although the United States has resources and exper-
tise to contribute to this initiative, a purely US-led approach 
would undermine the goal of having this be a more diverse and 
accessible resource with buy-in from the various communi-
ties involved. An advisory board that includes representatives 
from the continental regions from which clinicians will solicit 
images to oversee the project and the database will provide a 
more appropriate mechanism for defining the agenda, goals, 
and implementation of this international project.34 Involving 
local physicians and community members in the design of the 
database will help to craft the resource in a way that maximizes 
the benefits and minimizes the harms to the diverse communi-
ties in which it will be used. In an effort to prevent local power 
relationships from affecting the collection of the data, all col-
laborators will be briefed on how to properly ascertain ances-
try information, focusing on medical conditions and ancestral 
geographic origins.

A widely accessible morphological database that is freely 
available on the Internet is important for both justice and trans-
parency reasons. However, it also raises the possibility of unde-
sirable uses and unintended consequences of an open-access 
morphological database that are causes for concern. Requiring 
users to access the database via a screen that describes the 
intended uses of the database and to electronically sign a form 
agreeing to terms of use should help to mitigate this concern, 
although it does not provide a mechanism for enforcement of 
these terms. Unintended uses can also be minimized by digi-
tally protecting images so that they cannot be downloaded 
from the website and, as mentioned, so that sorting images by 
ancestral origin alone be prevented.

The recommended multinational oversight structure should 
be consulted to design an appropriate consent process for indi-
viduals who participate in the project. Practically speaking, the 
consent process needs to address the specific informational 
needs of each community involved (for example, local literacy 
levels and educational attainment).35 A well-designed, transpar-
ent consent process that is vetted by local leadership and local 
regulatory experts is more likely to be perceived as trustworthy 
by individual participants and their communities. In addition 
to their involvement in writing consent forms, local collabora-
tors should also be directly involved in identifying appropriate 
participants within their locales.36

There are additional considerations regarding the informed 
consent process that require further exploration. The process 
will need to inform potential participants about the privacy 
risks associated with publishing images and other data on the 
broad and international scale that is proposed for this project, 
and it will need to sufficiently address any relevant privacy reg-
ulations that govern the sharing of medical images and infor-
mation via the Internet. Given the young age of many of the 
potential subjects in the atlas, an appropriate mechanism for 
parental authorization will be an important component of this 
project as well. Similarly, a surrogate mechanism to authorize 
the participation of adults with limited cognitive capacity, as is 
characteristic of many of the conditions that will be included 
in the atlas, will be necessary. Decisions also need to be made 
about whether participants will be offered the choice to with-
draw their images from the database at a later date if they so 
choose, or whether their ability to withdraw will be limited 
once the images have been published in this resource.

cOncLUsiOn
The creation of new morphological atlases that take into 
account the broad diversity of the populations affected by 
genetic diseases is an important step in extending the benefits 
of medical genetics to the global populations who are currently 
underserved. Knowing that a child has a particular syndromic 
diagnosis can be lifesaving by providing important information 
about other significant organ systems that are often affected. 
In addition, an early and accurate diagnosis can enable physi-
cians to perform appropriate preventative care and give affected 
families an idea of what lies ahead. At the same time, there are 
a number of ethical considerations that should be addressed in 
any project that relies on the publication of images and genetic 
information from persons with dysmorphic features who come 
from a variety of ancestral backgrounds. Our goals in this paper 
were both constructive and preventive in nature, providing rec-
ommendations to guide the creation of a maximally beneficial 
resource while also mitigating potential problems with the 
project before they arise. Ultimately, we believe that the ethical 
concerns that have been identified, although serious, are out-
weighed by the potential benefits to populations who have not 
been included in such resources to date, and that appropriate 
steps can be taken to mitigate these ethical concerns.

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ACKNOWLEDGMENTS
This work was funded in part by the intramural research program 
of the National Human Genome Research Institute. The authors 
acknowledge the helpful feedback of Donald Hadley, Manjit Kaur, 
and participants at the Mid-Atlantic Bioethics Fellows’ Colloquium 
for earlier versions of this work. Written parental consent was 
obtained to publish the photographs of children with Down syn-
drome that are included in Figure 1.
The views expressed are the authors’ own. They do not represent the 
position or policy of the National Institutes of Health, the US Public 
Health Service, or the Department of Health and Human Services.

DISCLOSURE
The authors declare no conflict of interest.

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 Volume 18  |  Number 11  |  November 2016  |  GeneTics in medicine

http://www.independent.co.uk/arts-entertainment/tv/features/why-are-the-words-mongol-mongoloid-and-mongy-still-bandied-about-as-insults-9878557.html
http://www.independent.co.uk/arts-entertainment/tv/features/why-are-the-words-mongol-mongoloid-and-mongy-still-bandied-about-as-insults-9878557.html
http://www.independent.co.uk/arts-entertainment/tv/features/why-are-the-words-mongol-mongoloid-and-mongy-still-bandied-about-as-insults-9878557.html
http://www.buzzfeed.com/virginiahughes/is-this-doctors-app-a-digital-classroom-or medical-form/
http://www.buzzfeed.com/virginiahughes/is-this-doctors-app-a-digital-classroom-or medical-form/

	Towards a more representative morphology: clinical and ethical considerations for including diverse populations in diagnostic genetic atlases
	Main
	Ethical Considerations
	Recommendations
	Conclusion
	Disclosure
	Acknowledgements
	References