Human enhancement through the lens of experimental and speculative neurotechnologies

Teunisse, Wessel; Youssef, Sandra; Schmidt, Markus

doi:10.1002/hbe2.179

Cited by 6 publications

(11 citation statements)

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“…There is a growing number of people, who are involved in a number of research and development activities in the field of neurotechnologies (NT), inside and outside the academic and institutional context, to build such devices for themselves or others. Whole new contexts of utilization are being created, often with the aim to make life easier and better, but also to explore the potentiality of NT enhanced human body and mind ( Teunisse et al, 2019 ). Human enhancement, sometimes called human augmentation, has increasingly become a topic of interest at the intersection of biological, genetic, neurological and technological innovations and advancements, also sparking a wave of attention by regulators, policy makers, commercial and grassroots interests.…”

Section: Introductionmentioning

confidence: 99%

“…Scientific and engineering advances make NT more and more accessible, not only for medical applications such as prostheses ( Dubljevic et al, 2014 ; Wexler, 2016 ), but also for non-medical, even do-it-yourself (DIY) use ( Wexler, 2016 ; 2017 ) and human enhancement ( Egner and Gruzelier, 2003 ; Fregni et al, 2005 ; Dockery et al, 2009 ; Meinzer et al, 2014 ). The reduction in cost and increased availability of materials, software and ways to implant devices into the human body makes NT more accessible for the do-it-yourself (DIY) community and neurohackers ( Wexler, 2016 ; Teunisse et al, 2019 ). While some researchers have attempted to engage with NT user groups to improve, e.g., BCI tools ( Stahl et al, 2017 ) the DIY community is different from user groups as they have their own (research) goals.…”

Section: Introductionmentioning

confidence: 99%

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Pioneering neurohackers: between egocentric human enhancement and altruistic sacrifice

Seyfried,

Youssef,

Schmidt

2023

Front. Neurosci.

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The growing field of neurotechnology (NT) is becoming more and more accessible in terms of reduced costs, increasing availability and reliability of materials, and ways to implant devices. As in other engineering fields such as bio-or information technology, there is a growing community of pioneering hackers who (self-)experiment with NT and develop novel applications. While most debates about NT, its goals and ethical ramifications are usually conducted by professionals in the field (neuroscientists, −engineers, −ethicists), little is known within these institutional frameworks about the motivations, goals and visions of neurohackers and how they view ethical ramifications of NT therapeutics vs. human enhancement. In this study we draw on qualitative interviews with 13 of these neurohacking pioneers, who are interacting with NT from a grassroots perspective (i.e., a bottom-up and community/subculture-oriented approach), and shed light on: how they understand themselves in the context of human enhancement; what the role of invasive NTs is when it comes to identifying as a cyborg; if their practices show a clear distinction between therapy and enhancement; whether human enhancement is always about performance, optimization and functionality; and to which extent neurohackers contribute to “mainstreaming” NT.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Pioneering neurohackers: between egocentric human enhancement and altruistic sacrifice

Seyfried,

Youssef,

Schmidt

2023

Front. Neurosci.

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“…At this stage, they are mainly developed for people with disorders, and are thus largely assistive technologies, but some (particularly BCIs) are also used by people who are not disabled. Whether such agents will choose to use neuroprosthetics to enhance how they act on the world, perceive the world, and regulate their affect remains to be seen (Teunisse, Youssef, & Schmidt, 2019).…”

Section: Neuroprostheticsmentioning

confidence: 99%

Varieties of Artifacts: Embodied, Perceptual, Cognitive, and Affective

Heersmink

2021

Topics in Cognitive Science

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The primary goal of this essay is to provide a comprehensive overview and analysis of the various relations between material artifacts and the embodied mind. A secondary goal of this essay is to identify some of the trends in the design and use of artifacts. First, based on their functional properties, I identify four categories of artifacts co-opted by the embodied mind, namely (a) embodied artifacts, (b) perceptual artifacts, (c) cognitive artifacts, and (d) affective artifacts. These categories can overlap and so some artifacts are members of more than one category. I also identify some of the techniques (or skills) we use when interacting with artifacts. Identifying these categories of artifacts and techniques allows us to map the landscape of relations between embodied minds and the artifactual world. Second, having identified categories of artifacts and techniques, this essay then outlines some of the trends in the design and use of artifacts, focusing on neuroprosthetics, brain-computer interfaces, and personalization algorithms nudging their users toward particular epistemic paths of information consumption.

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“…For example, cochlear implants for partial restoration of hearing can under specific circumstances, such as in a very noisy environment, endow the patient with better than human hearing capabilities, when the microphone and software of the cochlear implant can filter out human voices from background noise; bionic eyes for retinitis pigmentosa to partially restore vision. [ 16 , 22 , 39 ] Some controversial uses of implants are to obtain new sensory perceptions such are the cases of the cyborg artist Neil Harbisson and the dancer Moon Ribas. [ 12 , 18 ] Harbisson was born completely color blind, but with an antenna implanted in his skull translates colors to sounds; but also he perceives infrared and ultraviolet light that are not part of the human visual spectrum.…”

Section: Future Directions Of Neurochips Applicationsmentioning

confidence: 99%

“…Nowadays, it was used to treat some difficulties in learning; in other cases are simply used to experiment new experiences, or even to obtain pleasure, for example, increasing erotic experiences. [ 9 , 12 , 18 , 21 , 35 , 36 , 39 , 43 ] A promising and exciting field of TMS is the medical application of personalized drug release responding to external commands (magnetic fields, temperature, or biochemical signals) for the management of oncological or metabolic diseases. [ 5 , 10 ] Particular attention should be paid to a research that is being performed in animals connecting the brain of rats through the network.…”

Section: Future Directions Of Neurochips Applicationsmentioning

confidence: 99%

Neurochips: Considerations from a neurosurgeon’s standpoint

Rabadán¹

2021

Surgical Neurology International

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A neurochip comprises a small device based on the brain-machine interfaces that emulate the functioning synapses. Its implant in the human body allows the interaction of the brain with a computer. Although the data-processing speed is still slower than that of the human brain, they are being developed. There is no ethical conflict as long as it is used for neural rehabilitation or to supply impaired or missing neurological functions. However, other applications emerge as controversial. To the best of our knowledge, there have no been publications about the neurosurgical role in the application of this neurotechnological advance. Deliberation on neurochips is primarily limited to a small circle of scholars such as neurotechnological engineers, artists, philosophers, and bioethicists. Why do we address neurosurgeons? They will be directly involved as they could be required to perform invasive procedures. Future neurosurgeons will have to be a different type of neurosurgeon. They will be part of interdisciplinary teams interacting with computer engineers, neurobiologist, and ethicists. Although a neurosurgeon is not expected to be an expert in all areas, they have to be familiar with them; they have to be prepared to determine indications, contraindications and risks of the procedures, participating in the decision-making processes, and even collaborating in the design of devices to preserve anatomic structures. Social, economic, and legal aspects are also inherent to the neurosurgical activity; therefore, these aspects should also be considered.

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Human enhancement through the lens of experimental and speculative neurotechnologies

Cited by 6 publications

References 58 publications

Pioneering neurohackers: between egocentric human enhancement and altruistic sacrifice

Pioneering neurohackers: between egocentric human enhancement and altruistic sacrifice

Varieties of Artifacts: Embodied, Perceptual, Cognitive, and Affective

Neurochips: Considerations from a neurosurgeon’s standpoint

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