Genetically engineered (GE) insects, such as the GE OX513A Aedes aegypti mosquitoes, have been designed to suppress their wild-type populations so as to reduce the transmission of vector-borne diseases in humans. Apart from the ecological and epidemiological uncertainties associated with this approach, such biotechnological approaches may be used by individual governments or the global community of nations to avoid addressing the underlying structural, systemic causes of those infections... We discuss here key ethical questions raised by the use of GE mosquitoes, (...) with the aim of fostering discussion between the public, researchers, policy makers, healthcare organizations, and regulatory agencies at the local, national, and international levels. We affect that goal by outlining a procedural approach to decision-making about the use of the “biotechnology” that goes beyond “community engagement.” The protocol we advocate for entails informed deliberations and decision-making at the community level. It is designed to ensure that the voices of the marginalized and vulnerable groups that would be disproportionately affected by the decision are heard during the community-wide discussions. Moreover, we make the case that the values embedded in the risk assessment should be identified so that the community can make an informed decision about the use of GE insects. In addition, we advocate for the involvement of a variety of actors whose responsibility would be to ensure that the community has the opportunity to make an informed decision based on deliberations about the use of the “biotechnology.”. (shrink)

Genetic engineering technologies are a subclass of the biotechnology family, and are concerned with the use of laboratory-based technologies to intervene with a given organism at the genetic level, i.e., the level of its DNA. This class of technologies could feasibly be used to treat diseases and disabilities, create disease-resistant crops, or even be used to enhance humans to make them more resistant to certain environmental conditions. However, both therapeutic and enhancement applications of genetic engineering raise serious (...) ethical concerns. This paper examines various objections to genetic engineering (as applied to humans) which have been raised in the literature, and presents a new way to frame these issues, and to look for solutions. Specifically, this paper frames genetic engineering technologies within the ‘design turn in applied ethics’ lens and thus situates these technologies as covarying with societal forces. The value sensitive design (VSD) approach to technology design is then appropriated as the conceptual framework in which genetic engineering technologies can be considered so that they can be designed for important human values. By doing so, this paper brings further nuance to the scholarship on genetic engineering technologies by discussing the sociotechnicity of genetic engineering systems rather than framing them as value-neutral tools that either support or constrain values based on how they are used. (shrink)

This chapter contains sections titled: The Various Uses of Genetic Engineering The Disability Rights Challenge to the Prevention of Disabilities The Goal of a World without Disabilities Use of Genetic Engineering to Enhance Normal Function Environmental versus Genetic Changes When are Enhancements Benefits? The Magnitude of Enhancement The Means Used for Enhancement Who is Using Genetic Engineering? Impact of Genetic Engineering on Fairness and Inequality Acknowledgments.

Genetic engineering evokes a number of objections that are not directed at the negative effects the technique might have on the health and welfare of the modified animals. The concept of animal integrity is often invoked to articulate these kind of objections. Moreover, in reaction to the advent of genetic engineering, the concept has been extended from the level of the individual animal to the level of the genome and of the species. However, the concept of animal integrity (...) was not developed in the context of genetic engineering. Given this external origin, the aim of this paper is to critically examine the assumption that the concept of integrity, including its extensions to the level of the genome and the species, is suitable to articulate and justify moral objections more specifically directed at the genetic engineering of animals. (shrink)

This paper describes some likely semiotic consequences of genetic engineering on what Gregory Bateson has called “the mental ecology” of future humans, consequences that are less often raised in discussions surrounding the safety of GMOs. The effects are as follows: an increased 1) habituation to the presence of GMOs in the environment, 2) normalization of empirically false assumptions grounding genetic reductionism, 3) acceptance that humans are capable and entitled to decide what constitutes an evolutionary improvement for a species, (...) 4) perception that the main source of creativity and problem solving in the biosphere is anthropogenic. Though there are some tensions between them, these effects tend to produce self-validating webs of ideas, actions, and environments, which may reinforce destructive habits of thought. Humans are unlikely to safely develop genetic technologies without confronting these escalating processes directly. Intervening in this mental ecology presents distinct challenges for educators, as will be discussed. (shrink)

Genetic engineering evokes a number of objections that are not directed at the negative effects the technique might have on the health and welfare of the modified animals. The concept of animal integrity is often invoked to articulate these kind of objections. Moreover, in reaction to the advent of genetic engineering, the concept has been extended from the level of the individual animal to the level of the genome and of the species. However, the concept of animal integrity (...) was not developed in the context of genetic engineering. Given this external origin, the aim of this paper is to critically examine the assumption that the concept of integrity, including its extensions to the level of the genome and the species, is suitable to articulate and justify moral objections more specifically directed at the genetic engineering of animals. (shrink)

Genetically engineered animals that are meant for release in the wild could significantly impact ecosystems given the interwoven or entangled existence of species. Therefore, among other things, it is all too important that regulatory agencies conduct entity appropriate, rigorous risk assessments that can be used for informed decision-making at the local, national and global levels about the release of those animals in the wild. In the United States, certain GE animals that are intended for release in the wild may be (...) regulated as new animal drugs by the Food and Drug Administration. This paper argues that the decision to treat them as new animal drugs is attributable to the influence of neoliberalism on the US biotechnology regulatory policy framework. The case is made that there should be public democratic deliberations and decision-making about the values and concerns that should guide the nation’s biotechnology regulatory policy paradigm, including the risk assessment process for GE animals meant for release in the wild. -/- . (shrink)

Genetic modification leads to several important moral issues. Up until now they have mainly been discussed from the viewpoint that only individual living beings, above all animals, are morally considerable. The standpoint that also collective entities such as species belong to the moral sphere have seldom been taken into account in a more thorough way, although it is advocated by several important environmental ethicists. The main purpose of this article is to analyze in more detail than often has been (...) done what the practical consequences of this ethical position would be for the use of genetic engineering on animals and plants. The practical consequences of the holistic standpoint (focused on collective entities) of Holmes Rolston, III, is compared with the practical consequences of the individualistic standpoints (focused on individual living beings) of Bernard E. Rollin and Philipp Balzer, Klaus Peter Rippe, and Peter Schaber, respectively. The article also discusses whether the claim that species are morally considerable is tenable as a foundation for policy decisions on genetic engineering. (shrink)

Genetic engineering of life forms could well have a profound effect upon our sense of the sacred. Integrating the experience of the sacred as George Bataille does, we can characterize it as a phenomenological encounter with prelinguistic, noncategoreal experience. This view of the sacred is similar to Friedrich Nietzsche's Dionysian experience or Rudolf Otto's mysterium tremendum and diminishes one's sense of self. It seems similar to the eighteenth‐century aesthetic categorization of “the sublime.” Despite the dominant rational approach to religiosity (...) in the United States, intimations of this experience persist in popular culture. What possible relationship does genetic engineering have to this allegedly inevitable and profound experience? If certain modifications of life occur, they are likely to create such an experience of the sacred in us. In principle, we can now resurrect the mammoth or even create beings designed to directly potentiate our experience of the numinous such as satyrs or centaurs. The creation of such beings could become an art form associated with awaking the sacred, in turn appropriated by religion, as art has always been. Such experimentation, though morally questionable, is probably inevitable. (shrink)

The Swiss expert report suggests thatthe inherent dignity of a living being be identifiedwith its inherent value. But the phrase ``inherentvalue of a living being'' seems to connote two conceptsof inherent value. One has a morally obligatingcharacter but is counterintuitive because of itsegalitarianism. The other is one of non-moral value.It is more compatible with considered intuitions butinsufficient for substantiating the expert report'sclaim that human beings have moral duties towardsanimals and plants. The paper discusses theseconcepts. Consideration is then given to the (...) problemof how discursive support can be generated for theexpert report's claim that human beings have the moralduty to abstain from impairing those functions andabilities of a nonuman being that members of itsspecies as a rule can practice. (shrink)

Genetic engineering often generates fear of out of control scientists creating Frankenstein creatures that will terrorize the general populace, especially in the cases of human-animal chimeras. While sometimes an accurate characterization of some researchers, this belief is often the result of repugnance for new technology rather than being rationally justified. To facilitate thoughtful discussion the moral issues raised by human-animal chimeras, ethicists and other stakeholders must develop a rational ethical framework before raw emotion has a chance of becoming the (...) dominating justification for public opinion and policy. Derek Parfit’s work on lives worth living for human beings can provide valuable insight into the morality of creating chimeras. As long as their lives are overall good, then bringing them into existence does not harm them even if they are used for medical research or procedures, or they are created to carry on the homo sapiens’ “family” line. (shrink)

The struggle over genetically-engineered (GE) maize in Mexico reveals a deep conflict over the criteria used in the governance of agri-food systems. Policy debate on the topic of GE maize has become “scientized,” granting experts a high level of political authority, and narrowing the regulatory domain to matters that can be adjudicated on the basis of scientific information or “managed” by environmental experts. While scientization would seem to narrow opportunities for public participation, this study finds that Mexican activists acting “in (...) defense of maize” engage science in multiple ways, using and producing scientific knowledge as well as treating scientific discussions as a stage for launching complex social critiques. Drawing from research in science and technology studies, this article assesses the impacts and pitfalls of three tactics used by maize activists that respond to the scientization of biotechnology politics: (1) using scientific information as a resource; (2) participating in scientific research; and (3) reframing policy problems as broadly social, rather than as solely scientific or technical. The obstacles that maize activists have faced in carrying out each of these efforts indicate that despite diverse and sophisticated engagements between social movements and the scientific field, scientization remains a significant institutional barrier to democratizing agricultural governance. (shrink)

Human genetic engineering may soon be possible. The gathering debate about this prospect already threatens to become mired in irresolvable disagreement. After surveying the scientific and technological developments that have brought us to this pass, _The Ethics of Genetic Engineering_ focuses on the ethical and policy debate, noting the deep divide that separates proponents and opponents. The book locates the source of this divide in differing framing assumptions: reductionist pluralist on one side, holist communitarian on the other. The (...) book argues that we must bridge this divide, drawing on the resources from both encampments, if we are to understand and cope with the distinctive problems posed by genetic engineering. These problems, termed "fractious problems," are novel, complex, ethically fraught, unavoidably of public concern, and unavoidably divisive. Berry examines three prominent ethical and political theories – utilitarianism, Kantianism, and virtue ethics – to consider their competency in bridging the divide and addressing these fractious problems. The book concludes that virtue ethics can best guide parental decision making and that a new policymaking approach sketched here, a "navigational approach," can best guide policymaking. These approaches enable us to gain a rich understanding of the problems posed and to craft resolutions adequate to their challenges. (shrink)

In my essay I consider the imaginary case of a future mother who refuses to undergo genetic alteration on her germline although she knows that her, as yet unconceived, child will have a serious genetic disorder. I analyze the good and bad points of two branches of arguments directed against her decision, consequentialist and rights-based. Then I discuss whether accepting one line of these arguments or the other makes a difference in moral assessment. I conclude that, although from (...) the preanalytical perspective we strongly oppose the refusal of genetic treatment in my imaginary case, it is probably impossible to construct one coherent theory which embraces all possible moral dilemmas triggered by our actions which affect the number and the identity of future people. (shrink)

(2008). Genetic Engineering and the Speciation of Superions from Humans. World Futures: Vol. 64, Postformal Thought and Hierarchical Complexity, pp. 436-443.

Imagine a world in which as part of their basic substances tomatoes contain fish and tobacco, potatoes contain chicken, moths and other insects, and corn contains fireflies. Is this science-fiction? No, these plant-animal hybrids already exist today and may soon be on your supermarket shelves without any special labeling to warn you. Furthermore, in a few years the types of these genetically engineered "vegetables" are sure to increase and may very possibly also include human genes. If you are a vegetarian, (...) do you want to be in the position of inadvertently eating vegetables that are part meat? Even if you are not a vegetarian, are you ready to become a cannibal and eat foods that are part human being? (shrink)

The use of genetic engineering is increasingly discussed for nature conservation. At the same time, recent animal ethics approaches debate whether humans should genetically engineer wild animals to improve their welfare. This paper examines if obligations towards wild sentient animals require humans to genetically engineering wild animals, while arguing that there is no moral need to do so. The focus is on arguments from animal ethics, but they are linked to conservation ethics, highlighting the often neglected overlap between the (...) two fields. The paper emphasizes that a) the benefits of genetic engineering are overestimated and at the same time harms from its development and use underestimated, b) the assumption that genetic engineering is an appropriate ‘last resort’ tool is wrong, c) many arguments in favor of genetic engineering are based on an inadequate understanding of ecology and biotechnological processes, and d) the debate downplays the importance of self-determination for wild animals. (shrink)

When God gave humankind dominion over the earth he may not have known exactly what we would be able to do with it. The technical capacities to which the production and reproduction of our everyday life have given rise have grown at an astonishing and, it seems, ever-increasing rate. The instruments that we use to do work on the world have become sharper and more refined, and the implications of human interventions in the nonhuman environment are much more far-reaching than (...) could have been imagined even forty years ago. It has become something of a cliche to say that our technical abilities have outstripped the wisdom to know when, where, and how we should appropriately use them, but techniques such as genetic engineering invite the dusting-off of the cliche and the asking of the question implicit in it: We know we can splice genes, but should we splice them? We might of course come to the conclusion that we should only splice some of them some of the time, but even arriving at that conclusion presupposes that the ethical question has been asked and answered. (shrink)

There are many ways that biological theory can inform ethical discussions of genetic engineering and biomedical enhancement. In this essay, we highlight some of these potential contributions, and along the way provide a synthetic overview of the papers that comprise this special issue. We begin by comparing and contrasting genetic engineering with programs of selective breeding that led to the domestication of plants and animals, and we consider how genetic engineering differs from other contemporary biotechnologies such as (...) embryo selection. We go on to consider the implications of genetic engineering for human nature, human evolution, and persistence of the human species. Finally, we question whether genetic interventions warrant the extraordinary ethical scrutiny they are often given, and we show how the misleading “genetic blueprint” metaphor has imposed a faulty structure on the enhancement debate. We conclude by considering the nature of biological development and the sobering limits it places on what genetic engineering can reasonably hope to achieve. (shrink)

The debate over whether germ-line genetic engineering is justified on the basis of the consent or presumed consent of future generations is mired in philosophical confusion. Because of this, the principle of informed consent fails to provide a reason to restrict germ-line genetic engineering. Most recent bioethicists ground the consent requirement on individual autonomy. While conceptually coherent, the notion of individual autonomy also fails to provide a reason for prohibiting germ-line genetic engineering. Moreover, it offers little in (...) the way of useful guidance for regulating genetic engineering. I argue, however, that respect for autonomy in the sense of moral agency – the ability to reflect on moral considerations and conform one’s behavior to those reflections – provides a principle that can be used for a nuanced evaluation of proposals for genetic engineering. (shrink)

Genetic engineering is a rapidly evolving field of research with potentially powerful therapeutic applications. The technology CRISPR-Cas9 not only has improved the accuracy and overall feasbility of genome editing but also has increased access to users by lowering cost and increasing usability and speed. The potential benefits of genetic engineering may come with an increased risk of off-target events or carcinogenic growth. Germ-line cell therapy may also pose risks to potential progeny and thus have an additional burden of (...) proof for safety. Persons responsible for evaluating the ethics of genetic-engineering research programs or clinical trials should do so in light of the nature, integrity, and totality of the human person. Recent news of the implantation and birth of genetically engineered human embryos is just one example of increased rogue science. Health care institutions should consider what steps can be taken to prevent or slow this trend. (shrink)

The current debate about labeling genetically engineered (GE) food focuses on food derived from GE crops, neglecting food derived from GE animals. This is not surprising, as GE animal products have not yet reached the market. Participants in the debate may also be assuming that conclusions about GE crops automatically extend to GE animals. But there are two GE animals - the Enviropig and the AquAdvantage Bred salmon - that are approaching the market, animals raise more ethical issues than plants, (...) and U.S. regulations treat animal products differently from crops. This paper therefore examines the specific question of whether there should be mandatory labeling on all food products derived from GE animals. We examine the likely regulatory pathways, salient differences between GE animals and GE crops, and relevant social science research on consumers’ attitudes. We argue that on any of the likely pathways, the relevant agency has a democratic obligation to require labeling for all GE animal food products. (shrink)

Many of the existing ethical analyses of genetic engineering technologies (GET) focus on how they can be used to enhance individuals—to improve individual well-being, health and cognition. There is a gap in the current literature about the specific ways enhancement technologies could be used to improve our populations and species, viewed as a whole. In this paper, I explore how GET may be used to enhance the species through improvements in the gene pool. I argue one aspect of the (...) species that may be desirable to enhance is ‘persistence’ or long-term viability. I then look at some of the ways in which GET could be used to improve human persistence and argue that the use of GET to secure benefits for individuals may compromise persistence. This suggests conflicts between uses of GET to enhance individuals and uses to promote the persistence of the species may occur. As GET are further developed, the likelihood that these conflicts will actually arise, and how we should resolve them if they do, will need to be considered. (shrink)

What might it be like to be a Buddhist in a future world where your life started with your parents designing your genes? In addition to screening for unwanted genetic diseases, they would have selected your genes for sex; height; eye, hair, and skin color; and, if your parents are Buddhists, maybe even for genes that allow you to sit easily in the full lotus position. Pressured by current social fads, they may also have chosen genes whose overall functions (...) are not clearly understood but are rumored to be connected with temperament, intelligence, mindfulness, and perhaps psychic powers. (There is no longer any need to search for reincarnated lamas. They now clone themselves and get reborn in their own clones.) If your parents are poor, they may have been paid to design you with genes tailored for a particular occupation, together with a pre-birth contract for future employment. As in the film Gattaca, you probably belong to a clearly defined social class according to the degree of your genetic enhancement. Of course there may still be a few weird, unenhanced naturals-by-choice meditating in the mountains. (shrink)

Many consumers view genetically engineered foods with suspicion partly because the food industry has taught them to do so. Consumers learn from advertisements and labels that the foods they buy are all natural only to realize that that is not the case. The food industry wishes to embrace the efficiencies offered by advances in genetic engineering, but this technology belies the image of nature to which the food industry constantly and conspicuously appeals. Consumers who believe genetically modified foods are (...) not “natural” will regard them as risky and undesirable. (shrink)

This book describes specific, well-know controversies in the genetic modification debate and connects them to deeper philosophical issues in philosophy of technology. It contributes to the current, far-reaching deliberations about the future of food, agriculture and society. Controversies over so-called Genetically Modified Organisms regularly appear in the press. The biotechnology debate has settled into a long-term philosophical dispute. The discussion goes much deeper than the initial empirical questions about whether or not GM food and crops are safe for human (...) consumption or pose environmental harms that dominated news reports. In fact, the implications of this debate extend beyond the sphere of food and agriculture to encompass the general role of science and technology in society. The GM controversy provides an occasion to explore important issues in philosophy of technology. Researchers, teachers and students interested in agricultural biotechnology, philosophy of technology and the future of food and agriculture will find this exploration timely and thought provoking. (shrink)

In the past few decades, increased awareness of environmental pollution has led to the exploitation of microbial metabolic potential in the construction of several genetically engineered microorganisms (GEMs) for bioremediation purposes. At the same time, environmental concerns and regulatory constraints have limited the in situ application of GEMs, the ultimate objective behind their development. In order to address the anticipated risks due to the uncontrolled survival/dispersal of GEMs or recombinant plasmids into the environment, some attempts have been made to construct (...) systems that would contain the released organisms. This article discusses the designing of safer genetically engineered organisms for environmental release with specific emphasis on the use of bacterial plasmid addiction systems to limit their survival thus minimizing the anticipated risk. We also conceptualize a novel strategy to construct “Suicidal Genetically Engineered Microorganisms (SGEMs)” by exploring/combining the knowledge of different plasmid addiction systems (such as antisense RNA‐regulated plasmid addiction, proteic plasmid addiction etc.) and inducible degradative operons of bacteria. BioEssays 27:563–573, 2005. © 2005 Wiley Periodicals, Inc. (shrink)

The ArgumentMuslims share with others both the interest in and the concern about genetic engineering. Naturally their reactions and views stem from general Islamic dogma and from Islamic medical ethics, but they are not unaware of Western scientific data. Particularly relevant is the Islamic religious prohibition against “changing what Allah has created.” Muslim muftis try to offer practical solutions for individuals. Islamic law is concerned about maintaining pure lineage. Consanguineous matings are very common, but induced abortions are usually ruled (...) out. Cloning has reawakened among Muslims an old debate over the positive as well as hazardous aspects of genetic engineering. (shrink)

Genes are the fundamental chemical codes that determine the physical nature of all living things, from the tiniest single-celled organism to human beings. Genes make up the DNA, the cell-level master plan which determines how the organism is going to develop in all ways that are not environmentally influenced.

Building on the evidence from the impact of hybrid technology on varietal diversity loss, this paper explores ex ante the possible effects of introduction of Bt eggplant on on-farm varietal diversity of eggplant. The public–private partnership involved in the development and introduction of Bt eggplant provides a great opportunity to develop locally-adapted Bt open-pollinated varieties (OPVs) instead of having a limited number of generic hybrid varieties. The study shows that introduction of multiple Bt OPVs by public institutions will reduce the (...) rate of replacement of OPVs by hybrids and thus help in conserving varietal diversity. However, the cost of developing multiple Bt OPVs is high; hence policy makers need to look at alternative measures to maintain the varietal diversity of crops such as eggplant in its centers of diversity. (shrink)

Genetic engineering in general, and human genetic editing in particular, is revolutionizing humankind’s self-understanding: an evolved organism taking ever greater control of its own evolution. This Anthropocenic phenomenon is deeply equivocal (Gregg B. Human genetic engineering: biotic justice in the anthropocene? In: DellaSala D, Goldstein M (eds) Encyclopedia of the Anthropocene, vol 4. Elsevier, Oxford, pp 351–359, 2018). While delivering humans from some risks, it renders them vulnerable to unintended consequences as well. Even in the face of (...) seemingly intractable differences of opinion about how best to understand genetic manipulation culturally, and how to evaluate it ethically, political communities and international organizations alike must address its possible future legal regulation. Governments and other elite institutions would do well to include the general public, to the extent possible, in deliberations about regulation, even as genetic engineering is based on highly specialized knowledge. (shrink)

The aim of this paper is to expose the unique muddle in which moral philosophy finds itself with regard to genetic engineering. The latter can be essentially defined as the correcting of nature's mistakes at their source, the DNA acid molecule of the gene. I shall discuss the moral nature of genetic engineering with respect to a single issue: the potential harm it may inflict upon the autonomous individual. I shall also consider the distinctions between genetic engineering (...) and other activities affecting human existence, in order to establish that the moral issues presented by genetic engineering are unique to it. (shrink)

There are many risks involved in genetic engineering. The release of genetically altered organisms in the environment can increase human suffering, decrease animal welfare, and lead to ecological disasters. The containment of biotechnological material in laboratories and industrial plants contributes to the risk of accidental release, especially if the handling and storage are inadequate. The purely political dangers include intensified economic inequality, the possibility of large-scale eugenic programs, and totalitarian control over human lives. How should the acceptability of these (...) risks be determined? We argue that the assessment should be left to those who can be harmed by the decisions in question. Economic risks are acceptable, if they are condoned by the corporations and governments who take them. The risks imposed on laboratory personnel by the containment of dangerous materials ought to be evaluated by the laboratory personnel themselves. All other risks are more or less universal, and should therefore be assessed as democratically as possible. If risk-taking is based on the choices of those who can be harmed by the consequences, then, even if the undesired outcome is realized, the risk is acceptable, because it is embedded in their own system of ethical and epistemic values. (shrink)

This paper evaluates Sara Goering’s recent attempt to use the Rawlsian notion of the veil of ignorance as a tool for distinguishing permissible from impermissible forms of genetic engineering. I argue that her article fails due to a failure to include vital contextual information in the right way.

Genetically engineered organisms have been at the center of ethical debates among the public and regulators over their potential risks and benefits to the environment and society. Unlike the currently commercial GE crops that express resistance or tolerance to pesticides or herbicides, a new GE crop produces two bioactive nutrients and docosahexaenoic acid ) that heretofore have largely been produced only in aquatic environments. This represents a novel category of risk to ecosystem functioning. The present paper describes why growing oilseed (...) crops engineered to produce EPA and DHA means introducing into a terrestrial ecosystem a pair of highly bioactive nutrients that are novel to terrestrial ecosystems and why that may have ecological and physiological consequences. More importantly perhaps, this paper argues that discussion of this novel risk represents an opportunity to examine the way the debate over genetically modified crops is being conducted. (shrink)

In recent years, genetically engineered (GE) mosquitoes have been proposed as a public health measure against the high incidence of mosquito-borne diseases among the poor in regions of the global South. While uncertainties as well as risks for humans and ecosystems are entailed by the open-release of GE mosquitoes, a powerful global health governance non-state organization is funding the development of and advocating the use of those bio-technologies as public health tools. In August 2016, the US Food and Drug Agency (...) (FDA) approved the uncaged field trial of a GE Aedes aegypti mosquito in Key Haven, Florida. The FDA’s decision was based on its assessment of the risks of the proposed experimental public health research project. The FDA is considered a global regulatory standard setter. So, its approval of the uncaged field trial could be used by proponents of GE mosquitoes to urge countries in the global South to permit the use of those bio-technologies. -/- From a public health ethics perspective, this paper evaluates the FDA’s 2016 risk assessment of the proposed uncaged field trial of the GE mosquito to determine whether it qualified as a realistic risk evaluation. -/- The FDA’s risk assessment of the proposed uncaged field trial did not proximate the conditions under which the GE mosquitoes would be used in regions of the global South where there is a high prevalence of mosquito-borne diseases. -/- Given that health and disease have political-economic determinants, whether a risk assessment of a product is realistic or not particularly matters with respect to interventions meant for public health problems that disproportionately impact socio-economically marginalized populations. If ineffective public health interventions are adopted based on risk evaluations that do not closely mirror the conditions under which those products would actually be used, there could be public health and ethical costs for those populations. (shrink)

When God gave humankind dominion over the earth he may not have known exactly what we would be able to do with it. The technical capacities to which the production and reproduction of our everyday life have given rise have grown at an astonishing and, it seems, ever-increasing rate. The instruments that we use to do work on the world have become sharper and more refined, and the implications of human interventions in the nonhuman environment are much more far-reaching than (...) could have been imagined even forty years ago. It has become something of a cliche to say that our technical abilities have outstripped the wisdom to know when, where, and how we should appropriately use them, but techniques such as genetic engineering invite the dusting-off of the cliche and the asking of the question implicit in it: We know we can splice genes, but should we splice them? We might of course come to the conclusion that we should only splice some of them some of the time, but even arriving at that conclusion presupposes that the ethical question has been asked and answered. (shrink)

There is an ongoing debate about genetic engineering (GE) in food production. Supporters argue that it makes crops more resilient to stresses, such as drought or pests, and should be considered by researchers as a technology to address issues of global food security, whereas opponents put forward that GE crops serve only the economic interests of transnational agrifood-firms and have not yet delivered on their promises to address food shortage and nutrient supply. To address discourse failure regarding the GE (...) debate, research needs to understand better what drives the divergent positions and which moral attitudes fuel the mental models of GE supporters and opponents. Hence, this study investigates moral attitudes regarding GE opposition and support in Germany. Results show that GE opponents are significantly more absolutist than supporters and significantly less likely to hold outcome-based views. Furthermore, GE opponents are more willing to donate for preventing GE admission than supporters are willing to donate for promoting GE admission. Our results shed light on why the divide between opponents and supporters in the German GE debate could remain stark and stable for so long. (shrink)

Imagine a world where everyone is healthy, intelligent, long living and happy. Intuitively this seems wonderful, albeit unrealistic. However, recent scientific developments in genetic engineering, namely CRISPR/Cas bring the question into public discourse, how the genetic enhancement of humans should be evaluated morally.

The paper argues that we should not genetically engineer hogs to suit the preferences of farmers and consumers.