Metaphors used to describe new technologies mediate public understanding of the innovations. Analyzing the linguistic, rhetorical, and affective aspects of these metaphors opens the range of issues available for bioethical scrutiny and increases public accountability. This article shows how such a multidisciplinary approach can be useful by looking at a set of texts about one issue, the use of a newly developed technique for genetic modification, CRISPRcas9.

The free-energy principle states that all systems that minimize their free energy resist a tendency to physical disintegration. Originally proposed to account for perception, learning, and action, the free-energy principle has been applied to the evolution, development, morphology, anatomy and function of the brain, and has been called a postulate, an unfalsifiable principle, a natural law, and an imperative. While it might afford a theoretical foundation for understanding the relationship between environment, life, and mind, its epistemic status is unclear. (...) Also unclear is how the free-energy principle relates to prominent theoretical approaches to life science phenomena, such as organicism and mechanism. This paper clarifies both issues, and identifies limits and prospects for the free-energy principle as a first principle in the life sciences. (shrink)

This second edition of Life Science Ethics includes four essays not found in the first edition: Richard Haynes on “Animals in Research” Stephen M. Gardiner on “Climate Change” Christopher Kelty on “Nanotechnology” Gary Comstock on “Genetically Modified Foods” and a revised and expanded version of the chapter on “Farms” in which Stephen Carpenter joins Charles Taliaferro as author. In addition, Part III has been thoroughly revised with the goal of focusing attention on salient examples. Three new case studies (...) have been added: Robert Streiffer and Sara Gavrell Ortiz on “Enviropigs” Donald F. Boesch, et al. on “Coastal Dead Zones” Deb Bennett-Woods on “Nanotechnology and Human Enhancement” The first edition was praised for providing instructors with a stimulating text that will help students hone their critical thinking skills. That text is here enhanced with treatments of critical new issues, including global warming, nanotechnology, and the possibility that bioengineering may be able to change human nature. The new edition includes classroom discussion questions for use in provoking and guiding in-class discussions. Part I introduces ethics, the relationship of religion to ethics, how we assess ethical arguments, and a method ethicists use to reason about ethical theories. Part II demonstrates the relevance of ethical reasoning to the environment, land, farms, food, biotechnology, genetically modified foods, animals in agriculture and research, climate change, and nanotechnology. Part III presents case studies for the topics found in Part II. Two appendices include exercises to help students learn systematic ways of thinking through ethical dilemmas and notes for instructors using the book as a text. (shrink)

Following recent debate on the relations between philosophy of science and the sciences, we wish to draw attention to some actual ways of training both young philosophers of science and young life scientists and clinicians. First, we recall a successful case of training philosophers of the life sciences in a strictly scientific environment. Second, after a brief review of the reasons why life scientists and clinicians are currently asking for more ethics, more methodology of (...) class='Hi'>science, and more philosophy of science in the training of life scientists and clinicians, we present two training models that could spur the discussion on how to meet the requests coming from the scientific community. We argue that in order to reflect on mutual relations between philosophy of science and the sciences and to foster proper interactions, issues regarding the topics considered, the features of educational curricula, and the institutional organizations should be addressed jointly. (shrink)

The life sciences are increasingly being called on to produce “socially robust” knowledge that honors the social contract between science and society. This has resulted in the emergence of a number of “broad social issues” that reflect the ethical tensions in these social contracts. These issues are framed in a variety of ways around the world, evidenced by differences in regulations addressing them. It is important to question whether these variations are simply regulatory variations or in fact reflect (...) a contextual approach to ethics that brings into question the existence of a system of “global scientific ethics”. Nonetheless, within ethics education for scientists these broad social issues are often presented using this scheme of global ethics due to legacies of science ethics pedagogy. This paper suggests this may present barriers to fostering international discourse between communities of scientists, and may cause difficulties in harmonizing (and transporting) national regulations for the governance of these issues. Reinterpreting these variations according to how the content of ethical principles is attributed by communities is proposed as crucial for developing a robust international discourse. To illustrate this, the paper offers some empirical fieldwork data that considers how the concept of dual-use (as a broad social issue) was discussed within African and UK laboratories. Demonstrating that African scientists reshaped the concept of dual-use according to their own research environmental pressures and ascribed alternative content to the principles that underpin it, suggests that the limitations of a “global scientific ethics” system for these issues cannot be ignored. (shrink)

Life sciences and emerging technologies raise a plethora of issues. Besides practical, bioethical and policy issues, they have broader, cultural implications as well, affecting and reflecting our zeitgeist and world-view, challenging our understanding of life, nature and ourselves as human beings, and reframing the human condition on a planetary scale. In accordance with the aims and scope of the journal, LSSP aims to foster engaged scholarship into the societal dimensions of emerging life sciences (Chadwick and Zwart 2013) (...) and via this thematic series, the journal provides a podium for authors who intend to address concrete issues from a ‘continental philosophical’ perspective, which may in- clude (post)phenomenology, hermeneutics, dialectics, (post)structuralism, psychoanalysis, critical theory and similar approaches. The series aims to contribute to a diagnostics of the present and a prognostics of the future, focusing on critical normative challenges (such as embodiment, intimate technologies, social justice, biopower, nanomedicine, human enhancement and the anthropocene) and building on the work of key authors such as Hegel (1830), Heidegger (1953, 1953/1954), Bachelard (1938), Canguilhem (1975), Lacan (1966, 1969-1970/1991), Habermas (1968), Serres (1972), Foucault (1969), Žižek (2006/2009), Stiegler (2010), Sloterdijk (2001, 2009) and others, but targeting con- crete up-to-date events and case studies against the backdrop of broader developments within the techno-scientific culture. (shrink)

This chapter provides a brief overview of the increasing importance of experimentation in the life sciences from the seventeenth century to the present day. In the wake of the Scientific Revolution initiated in physics, numerous scientists have regularly attempted to introduce experimentation and the quantification of phenomena into the life sciences. These attempts have been difficult and have systematically come up against the fact that living organisms are individuals, i.e. both totalities that are difficult to decompose and transient (...) results of an evolutionary process that gives them specific characteristics. Experimentation has thus only been possible in biology thanks to the adaptation of a mechanistic perspective to such particularities of living bodies. (shrink)

Both science and theology involve philosophy. They both involve reasoned argument, evaluation of possible explanations, clarification of concepts, ways of interpreting experience, understanding the present significance of what has gone before us, and other such eminently philosophical tasks. They both involve philosophy, especially when they enter into dialogue with each other. In fact, they involve philosophical thinking even when they may not be aware of it. In this paper I will explore a specific area of philosophy that is particularly (...) important as a bridge between theology and science. I am referring to the area of meaning. Questions regarding meaning are fundamental because whatever is said about the nature of life, by scientists, by theologians, or by anyone else, must be expressed in meaningful words. Meaning is like the ground we walk on. It constitutes what we need to proceed with our activity. Without solid ground under our feet, we cannot go anywhere. (shrink)

Although in the last decades increasingly more philosophers have paid attention to the life sciences, traditionally physics has dominated general philosophy of science. Does a focus on the life sciences and medicine produce a different philosophy of science and indeed a different conception of knowledge? Here Cristina Chimisso does not attempt to give a comprehensive answer to this question; rather, she presents a case study focussed on Georges Canguilhem. Canguilhem continued the philosophical tradition that we now (...) call historical epistemology, and always referred very closely to the philosophy of Gaston Bachelard. However, whereas Bachelard primarily studied the history of chemistry and physics, Canguilhem turned to the life sciences, medicine and psychiatry. Chimisso investigates their respective conceptions and uses of norms. Chimisso argues that some crucial differences in how they regarded norms, seldom emphasised by Canguilhem himself and indeed by critics, stem from the sciences on which they concentrated. (shrink)

Available for the first time in English, Roger's masterwork of intellectual history situates the life sciences within the larger context of French Enlightenment thought and the history of institutions.

This book distills six decades of diary entries on science, religion, truth, ethics, success, and society by Walter Kistler, scientist, industrialist, and philanthropist. The book explores these subjects through the lenses of analysis and implication, and presents the compelling findings of an extraordinary, lifelong, intellectual odyssey.

Field Life examines the practice of science in the field in the Great Plains and Rocky Mountains of the American West between the 1860s and the 1910s, when the railroad was the dominant form of long-distance transportation. Grounded in approaches from environmental history and the history of technology, it emphasizes the material basis of scientific fieldwork, joining together the human labor that produced knowledge with the natural world in which those practices were embedded. Four distinct modes of field (...) practice, which were shared by different field science disciplines, proliferated during this period—surveys, lay networks, quarries, and stations—and this book explores the dynamics that underpinned each of them. Using two diverse case studies to animate each mode of practice, as well as the making of the field as a place for science, Field Life combines textured analysis of specific examples of field science on the ground with wider discussion of the commonalities in the practices of a diverse array of field sciences, including the earth and physical sciences, the life and agricultural sciences, and the human sciences. By situating science in its regional environmental context, Field Life analyzes the intersection between the cosmopolitan knowledge of science and the experiential knowledge of people living in the field. Examples of field science in the Plains and Rockies range widely: geological surveys and weather observing networks, quarries to uncover dinosaur fossils and archaeological remains, and branch agricultural experiment stations and mountain biological field stations. (shrink)

This article critically engages with the influential theory of ‘‘molecularized biopower’’ and ‘‘politics of life’’ developed by Paul Rabinow and Nikolas Rose. Molecularization is assumed to signal the end of population-centred biopolitics and the disciplining of subjects as described by Foucault, and the rise of new forms of biosociality and biological citizenship. Drawing on empirical work in Science and Technology Studies, we argue that this account is limited by a focus on novelty and assumptions about the transformative power (...) of the genetic life sciences. We suggest that biopower consists of a more complex cluster of relationships between the molecular and the population. The biological existence of different human beings is politicized through different complementary and competing discourses around medical therapies, choices at the beginning and end of life, public health, environment, migration and border controls, implying a multiple rather than a singular politics of life. (shrink)

"All art should become science and all science art; poetry and philosophy should be made one." Friedrich Schlegel's words perfectly capture the project of the German Romantics, who believed that the aesthetic approaches of art and literature could reveal patterns and meaning in nature that couldn't be uncovered through rationalistic philosophy and science alone. In this wide-ranging work, Robert J. Richards shows how the Romantic conception of the world influenced (and was influenced by) both the lives of (...) the people who held it and the development of nineteenth-century science. Integrating Romantic literature, science, and philosophy with an intimate knowledge of the individuals involved—from Goethe and the brothers Schlegel to Humboldt and Friedrich and Caroline Schelling—Richards demonstrates how their tempestuous lives shaped their ideas as profoundly as their intellectual and cultural heritage. He focuses especially on how Romantic concepts of the self, as well as aesthetic and moral considerations—all tempered by personal relationships—altered scientific representations of nature. Although historians have long considered Romanticism at best a minor tributary to scientific thought, Richards moves it to the center of the main currents of nineteenth-century biology, culminating in the conception of nature that underlies Darwin's evolutionary theory. Uniting the personal and poetic aspects of philosophy and science in a way that the German Romantics themselves would have honored, The Romantic Conception of Life alters how we look at Romanticism and nineteenth-century biology. (shrink)

In this interview, Anne Fagot-Largeault discusses with Thierry Bardini her recollections of the life and work of French philosopher Gilbert Simondon. The discussion covers Simondon’s theory of individuation and considers its influences on contemporary thinkers such as Gilles Deleuze and François Laruelle. Fagot-Largeault situates Simondon’s thinking within the broader context of 20th-century biological research and the development of life sciences. Informed by her personal association and experiences working with Simondon, her reminiscences shed light on the unique character of (...) Simondon as a person and as a thinker. (shrink)

Investigators of animal behavior since the eighteenth century have sought to make their work integral to the enterprises of natural history and/or the life sciences. In their efforts to do so, they have frequently based their claims of authority on the advantages offered by the special places where they have conducted their research. The zoo, the laboratory, and the field have been major settings for animal behavior studies. The issue of the relative advantages of these different sites has been (...) a persistent one in the history of animal behavior studies up to and including the work of the ethologists of the twentieth century. (shrink)

This volume explores the intersection between early modern philosophy and the life sciences by presenting the contributions of important but often neglected figures such as Cudworth, Grew, Glisson, Hieronymus Fabricius, Stahl, Gallego, Hartsoeker, and More, as well as familiar figures such as Descartes, Spinoza, Leibniz, Malebranche, and Kant.

The successful decoding of human genome and subsequent advances in new life sciences innovation create technological presuppositions of a new possibility of justice i.e. the just distribution of both social and natural goods. Although Rawlsians attempt to expand their theory to include this new possibility, they fail to provide plausible metrics of social justice in the genomics and post-genomics era. By contrast, Senians seem to succeed to do so through their index of basic capabilities. This paper explores what might (...) be regarded as a Senian perspective of distributive justice in new life sciences innovation. The argument is that, by comparing freedoms instead of primary goods, the capability theory allows not only for the identification of injustices linked to natural lottery but also for their elimination through the use of new genomic technologies, including gene-based diagnostics, gene therapy, somatic cell engineering and germ-line engineering. These innovative technologies seem to have the potential to reduce variability in natural goods and therefore enable individuals to convert social goods into well-being or welfare. (shrink)

Formal principles governing best practices in classification and definition have for too long been neglected in the construction of biomedical ontologies, in ways which have important negative consequences for data integration and ontology alignment. We argue that the use of such principles in ontology construction can serve as a valuable tool in error-detection and also in supporting reliable manual curation. We argue also that such principles are a prerequisite for the successful application of advanced data integration techniques such as ontology-based (...) multi-database querying, automated ontology alignment and ontology-based text-mining. These theses are illustrated by means of a case study of the Gene Ontology, a project of increasing importance within the field of biomedical data integration. (shrink)

In this thesis we have examined the complex interaction between intellectual property rights, life sciences and global justice. Science and the innovations developed in its wake have an enormous effect on our daily lives, providing countless opportunities but also raising numerous problems of justice. The complexity of a problem however does not liberate society as a whole from moral responsibilities. Our intellectual property regimes clash at various points with human rights law and commonly held notions of justice.

Researchers in the life sciences often make uniqueness attributions; about branching events generating new species, the developmental processes generating novel traits and the distinctive cultural selection pressures faced by hominins. Yet since uniqueness implies non-recurrence, such attributions come freighted with epistemic consequences. Drawing on the work of Aviezer Tucker, we show that a common reaction to uniqueness attributions is pessimism: both about the strength of candidate explanations as well as the ability to even generate such explanations. Looking at two (...) case studies—elephant trunks and human teaching—we develop a more optimistic account. As we argue, uniqueness attributions are revisable claims about the availability of several different kinds of comparators. Yet even as researchers investigate the availability of such comparators, they are able to mobilize complex sets of empirical and theoretical tools. Rather than hindering scientific investigation, then, we argue that uniqueness attributions often spur the generation of a range of epistemic goods. (shrink)

In addition to being one of the world's most influential philosophers, Aristotle can also be credited with the creation of both the science of biology and the philosophy of biology. He was the first thinker to treat the investigations of the living world as a distinct inquiry with its own special concepts and principles. This book focuses on a seminal event in the history of biology - Aristotle's delineation of a special branch of theoretical knowledge devoted to the systematic (...) investigation of animals. Aristotle approached the creation of zoology with the tools of subtle and systematic philosophies of nature and of science that were then carefully tailored to the investigation of animals. The papers collected in this volume, written by a pre-eminent figure in the field of Aristotle's philosophy and biology, examine Aristotle's approach to biological inquiry and explanation, his concepts of matter, form and kind, and his teleology. (shrink)

Natural kinds have been a constant topic in philosophy throughout its history, but many issues pertaining to natural kinds still remain unresolved. This paper considers one of these issues: the epistemic role of natural kinds in scientific investigation. I begin by clarifying what is at stake for an individual scientific field when asking whether or not the field studies a natural kind. I use an example from life science, concerning how biologists explain the similar body shapes of fish (...) and cetaceans, to show that natural kinds play a central epistemic role in scientific explanations that cannot be delegated to other explanatory factors. A task for philosophy, then, is to come up with a theory of natural kinds that adequately accounts for the epistemic role of natural kinds in science. After having sketched the spectrum of available philosophical theories of natural kinds, I argue that none of the available theories adequately performs this task and that therefore the search is still open for a theory that does. (shrink)

This book explores Nietzsche's philosophical naturalism in its historical context, showing that his position is best understood against the background of encounters between neo-Kantianism and the life sciences in the nineteenth century. Analyzing most of Nietzsche's writings from the late 1860s onwards, Christian J. Emden reconstructs Nietzsche's naturalism and argues for a new understanding of his account of nature and normativity. Emden proposes historical reasons why Nietzsche came to adopt the position he did; his genealogy of values and his (...) account of a will to power are as much influenced by Kantian thought as they are by nineteenth-century debates on teleology, biological functions, and theories of evolution. This rich and wide-ranging study will be of interest to scholars and students of Nietzsche, the history of modern philosophy, intellectual history, and history of science. (shrink)

This paper criticizes the role of intuition-based ascriptions of cognition that are closely related to the ascription of mind. This practice hinders the explication of a clear and stable target domain for the cognitive sciences. To move forward, the proposal is to cut the notion of cognition free from such ascriptions and the intuition-based judgments that drive them. Instead, cognition is reinterpreted and developed as a scientific concept that is tied to a material domain of research. In this reading, cognition (...) becomes a changeable theoretical concept that can and must be adapted to the findings within this target domain. Taking humans as the best-established existing example of the relevant material target domain, this central case is extended to include all living systems. To clarify what it is about living systems that warrants their role as cognitive target domain, the new concept of cobolism is introduced as a complement to metabolism. Cobolism refers to the systematic ways in which each living system encompasses structures, processes and external events that maintain the fundamental metabolic processes that constitute the core of each living system. Cobolism is perfectly general, applies to bacterial and human cases alike, and provides a general format to describe wildly different cognitive organizations. It provides a clear target for the cognitive sciences to work on, turning them into what we can call the cognitive life sciences. (shrink)

Although scientific realism is the default position in the life sciences, philosophical accounts of realism are geared towards physics and run into trouble when applied to fields such as biology or neuroscience. In this paper, I formulate a new robustness-based version of entity realism, and show that it provides a plausible account of realism for the life sciences that is also continuous with scientific practice. It is based on the idea that if there are several independent ways of (...) measuring, detecting or deriving something, then we are justified in believing that it is real. I also consider several possible objections to robustness-based entity realism, discuss its relationship to ontic structural realism, and show how it has the potential to provide a novel response to the pessimistic induction argument. (shrink)

The author considers ethical obligations in relation to all living beings. As a result, he formulates the guiding principle of our actions - a bioethical imperative «Respect each living being as an end in itself and, if possible, treat it, as yourself». Based on this principle, you can pedagogically influence morality with the help of various scientific disciplines.

A unique introduction to the philosophy of science with special emphasis on the life sciences. Part I presents elementary but fundamental concepts and problems in epistemology and their relation to questions of scientific methodology. Part II deals with case studies from the history of biology which illustrate particular philosophical points while Part III progresses to more complex ideas as on the nature and methodology of science. Part IV discusses the limitations of scientific enquiry and its relations to (...) other systems of knowledge and interpretation. (shrink)