Deep-brain stimulation has been used to treat advanced Parkinson disease and other neurological and psychiatric disorders that have not responded to other treatments. While deep-brain stimulation can modulate overactive or underactive regions of the brain and thereby improve motor function, it can also cause changes in a patient’s thought and personality. This paper discusses the trade-offs between the physiological benefit of this technique and the potential psychological harm.

Implant ethics is defined here as the study of ethical aspects of the lasting introduction of technological devices into the human body. Whereas technological implants relieve us of some of the ethical problems connected with transplantation, other difficulties arise that are in need of careful analysis. A systematic approach to implant ethics is proposed. The major specific problems are identified as those concerning end of life issues (turning off devices), enhancement of human capabilities beyond normal levels, mental changes and personal (...) identity, and cultural effects. (shrink)

As neural implants transition from engineering design and testing into human subjects research, careful consideration must be paid to the ethical elements in developing research protocols. Although these ethical aspects may be framed by the design choices of the engineering, a number of challenging choices arise. In spite of many ethical considerations for neural implant technologies being shared with generic research ethics questions, there are subsets needing special attention. Even in considerations requiring increased attention, substantial overlap can be found with (...) research ethics questions for general medical implants and for psychiatric pharmaceuticals. The special attention to specific ethical questions in neural implants exists because of the value placed on preserving cognition and control as well as our continued memory of significant past research abuses in neurosurgery. This paper focuses on three issues of particular saliency to neural implant testing: inclusion/exclusion of subjects with psychiatric conditions, consent withdrawal of research subjects, and enhancement as a goal. (shrink)

Over the course of its first seven editions, Principles of Biomedical Ethics has proved to be, globally, the most widely used, authored work in biomedical ethics. It is unique in being a book in bioethics used in numerous disciplines for purposes of instruction in bioethics. Its framework of moral principles is authoritative for many professional associations and biomedical institutions-for instruction in both clinical ethics and research ethics. It has been widely used in several disciplines for purposes of teaching in the (...) classroom, during conferences, etc. (shrink)

In reference to the different approaches in philosophy(of medicine) of the nature of (medical) technology,this article introduces the topic of this specialissue of Theoretical Medicine and Bioethics, that is,the way the different forms of medical technologyfunction in everyday medical practice. The authorselaborate on the active role technology plays inshaping our views on disease, illness, and the body,whence in shaping our world.

Book reviewed in this article: Principles of Biomedical Ethics. By Tom L. Beauchamp and James F. Childress.

The application of neurostimulation techniques such as deep brain stimulation —often called a brain pacemaker for neurological conditions like Parkinson's disease —has generated “currents of hope.” Building on this hope, there is significant interest in applying neurostimulation to psychiatric disorders such as major depression and obsessive-compulsive disorder. These emerging neurosurgical practices raise a number of important ethical and social questions in matters of resource allocation, informed consent for vulnerable populations, and commercialization of research.

The vulnerability of patients receiving significantly innovative neurosurgical procedures, either as research or as non-standard therapy, presents particularly potent challenges for those attempting to substantially advance clinical Neurosurgical practice in the most ethically and efficacious manner. This beginning formulation has built into it several important notions about research participation, balancing values, and clinical advancement in the context of neurological illness. For the time being, allow vulnerability to act as a placeholder for circumstances or states of being wherein the established checks (...) and balances of power and interest are no longer sufficient in promoting the just treatment of persons. Further, the phrase to substantially advance Neurosurgical practice encompasses radical innovation as well as significant research into new procedures. Finally, few of these explorations involve true randomized placebo controlled trials, but rather they enroll patients rightfully hoping for some benefit by means of undergoing the procedure.When a neurosurgeon asks me, as an ethicist, to meet with a patient who has medically refractory disease and no good standard therapy options remaining, he is asking for help concerning whether to offer, as a last chance, an unproven therapy as either innovation or research. (shrink)

Deep brain stimulation (DBS) to different sites allows interfering with dysfunctional network function implicated in major depression. Because a prominent clinical feature of depression is anhedonia--the inability to experience pleasure from previously pleasurable activities--and because there is clear evidence of dysfunctions of the reward system in depression, DBS to the nucleus accumbens might offer a new possibility to target depressive symptomatology in otherwise treatment-resistant depression. Three patients suffering from extremely resistant forms of depression, who did not respond to pharmacotherapy, psychotherapy, (...) and electroconvulsive therapy, were implanted with bilateral DBS electrodes in the nucleus accumbens. Stimulation parameters were modified in a double-blind manner, and clinical ratings were assessed at each modification. Additionally, brain metabolism was assessed 1 week before and 1 week after stimulation onset. Clinical ratings improved in all three patients when the stimulator was on, and worsened in all three patients when the stimulator was turned off. Effects were observable immediately, and no side effects occurred in any of the patients. Using FDG-PET, significant changes in brain metabolism as a function of the stimulation in fronto-striatal networks were observed. No unwanted effects of DBS other than those directly related to the surgical procedure (eg pain at sites of implantation) were observed. Dysfunctions of the reward system--in which the nucleus accumbens is a key structure--are implicated in the neurobiology of major depression and might be responsible for impaired reward processing, as evidenced by the symptom of anhedonia. These preliminary findings suggest that DBS to the nucleus accumbens might be a hypothesis-guided approach for refractory major depression. (shrink)

This textbook introduces the reader to basic problems in the philosophy of science and ethics, mainly by means of examples from medicine. It is based on the conviction that philosophy, medical science, medical informatics, and medical ethics are overlapping disciplines. It claims that the philosophical lessons to learn from the twentieth century are not that nature is a 'social construction' and that 'anything goes' with respect to methodological and moral rules. Instead, it claims that there is scientific knowledge, but that (...) it is never completely secure; that there are norms, but that they are situation-bound; and that, therefore, it makes good sense to search for scientific truths and try to act in a morally decent way. Using philosophical catchwords, the authors advocate 'fallibilism' and 'particularism'; a combination that might be called 'pragmatic realism'. (shrink)

Revolutions in semiconductor device miniaturization, bioelectronics, and applied neural control technologies are enabling scientists to create machine-assisted minds, science fiction's “cyborgs.” In a paper published in 1999, we sought to draw attention to the advances in prosthetic devices, to the myriad of artificial implants, and to the early developments of this technology in cochlear and retinal implants. Our concern, then and now, was to draw attention to the ethical issues arising from these innovations. Since that time, breakthroughs have occurred at (...) a breathtaking pace. Scientists, researchers, and engineers using differing methodologies are pursuing the possibilities of direct interfaces between brains and machines. Technological innovations as such are neither good nor evil; it is the uses devised for them that create moral implications. As there can be ethical problems inherent in the proper human uses of technologies and because brain chips are a very likely future technology, it is prudent to formulate policies and regulations that will mitigate their ill effects before the technologies are widespread. Unlike genetic technologies, which have received widespread scrutiny within the scientific community, national governments, and international forums, brain–machine interfaces have received little social or ethical scrutiny. However, the potential of this technology to change and significantly affect humans is potentially far greater than that of genetic enhancements, because genetic enhancements are inherently limited by biology and the single location of an individual, whereas hybrids of human and machine are not so restricted. Today, intense interest is focused on the development of drugs to enhance memory; yet, these drugs merely promise an improvement of normal memory, not the encyclopedic recall of a computer-enhanced mind combined with the ability to share information at a distance. The potential of brain chips for transforming humanity are astounding. This paper describes advances in hybrid brain–machine interfaces, offers some likely hypotheses concerning future developments, reflects on the implications of combining cloning and transplanted brain chips, and suggests some potential methods of regulating these technologies. (shrink)

New medical technologies provide us with new possibilities in health care and health care research. Depending on their degree of novelty, they may as well present us with a whole range of unforeseen normative challenges. Partly, this is due to a lack of appropriate norms to perceive and handle new technologies. This article investigates our ways of establishing such norms. We argue that in this respect analogies have at least two normative functions: they inform both our understanding and our conduct. (...) Furthermore, as these functions are intertwined and can blur moral debates, a functional investigation of analogies can be a fruitful part of ethical analysis. We argue that although analogies can be conservative; because they bring old concepts to bear upon new ones, there are at least three ways in which they can be creative. First, understandings of new technologies are quite different from the analogies that established them, and come to be analogies themselves. That is, the concepts may turn out to be quite different from the analogies that established them. Second, analogies transpose similarities from one area into another, where they previously had no bearing. Third, analogies tend to have a figurative function, bringing in something new and different from the content of the analogies. We use research-biobanking as a practical example in our investigations. (shrink)

The current model of technology assessment treats ethics itself as just another problem‐solving technology. Ethics should resist this model to play a more critical role in technology assessment by better understanding the complex relationship between society, medicine, and technology—and by recasting how problems are defined.