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We Seek Not to Become Machines, But to Keep Up with Them – Article by Franco Cortese

We Seek Not to Become Machines, But to Keep Up with Them – Article by Franco Cortese

The New Renaissance Hat
Franco Cortese
July 14, 2013
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This article attempts to clarify four areas within the movement of Substrate-Independent Minds and the discipline of Whole-Brain Emulation that are particularly ripe for ready-hand misnomers and misconceptions.
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Substrate-Independence 101:

  • Substrate-Independence:
    It is Substrate-Independence for Mind in general, but not any specific mind in particular.
  • The Term “Uploading” Misconstrues More than it Clarifies:
    Once WBE is experimentally-verified, we won’t be using conventional or general-purpose computers like our desktop PCs to emulate real, specific persons.
  • The Computability of the Mind:
    This concept has nothing to do with the brain operating like a computer. The liver is just as computable as the brain; their difference is one of computational intensity, not category.
  • We Don’t Want to Become The Machines – We Want to Keep Up With Them!:
    SIM & WBE are sciences of life-extension first and foremost. It is not out of sheer technophilia, contemptuous “contempt of the flesh”, or wanton want of machinedom that proponents of Uploading support it. It is, for many, because we fear that Recursively Self-Modifying AI will implement an intelligence explosion before Humanity has a chance to come along for the ride. The creation of any one entity superintelligent to the rest constitutes both an existential risk and an antithetical affront to Man, whose sole central and incessant essence is to make himself to an increasingly greater degree, and not to have some artificial god do it for him or tell him how to do it.
Substrate-Independence
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The term “substrate-independence” denotes the philosophical thesis of functionalism – that what is important about the mind and its constitutive sub-systems and processes is their relative function. If such a function could be recreated using an alternate series of component parts or procedural steps, or can be recreated on another substrate entirely, the philosophical thesis of Functionalism holds that it should be the same as the original, experientially speaking.

However, one rather common and ready-at-hand misinterpretation stemming from the term “Substrate-Independence” is the notion that we as personal selves could arbitrarily jump from mental substrate to mental substrate, since mind is software and software can be run on various general-purpose machines. The most common form of this notion is exemplified by scenarios laid out in various Greg Egan novels and stories, wherein a given person sends their mind encoded as a wireless signal to some distant receiver, to be reinstantiated upon arrival.

The term “substrate-independent minds” should denote substrate independence for the minds in general, again, the philosophical thesis of functionalism, and not this second, illegitimate notion. In order to send oneself as such a signal, one would have to put all the processes constituting the mind “on pause” – that is, all causal interaction and thus causal continuity between the software components and processes instantiating our selves would be halted while the software was encoded as a signal, transmitted and subsequently decoded. We could expect this to be equivalent to temporary brain death or to destructive uploading without any sort of gradual replacement, integration, or transfer procedure. Each of these scenarios incurs the ceasing of all causal interaction and causal continuity among the constitutive components and processes instantiating the mind. Yes, we would be instantiated upon reaching our destination, but we can expect this to be as phenomenally discontinuous as brain death or destructive uploading.

There is much talk in the philosophical and futurist circles – where Substrate-Independent Minds are a familiar topic and a common point of discussion – on how the mind is software. This sentiment ultimately derives from functionalism, and the notion that when it comes to mind it is not the material of the brain that matters, but the process(es) emerging therefrom. And due to the fact that almost all software is designed to as to be implemented on general-purpose (i.e., standardized) hardware, that we should likewise be able to transfer the software of the mind into a new physical computational substrate with as much ease as we do software. While we would emerge from such a transfer functionally isomorphic with ourselves prior to the jump from computer to computer, we can expect this to be the phenomenal equivalent of brain death or destructive uploading, again, because all causal interaction and continuity between that software’s constitutive sub-processes has been discontinued. We would have been put on pause in the time between leaving one computer, whether as static signal or static solid-state storage, and arriving at the other.

This is not to say that we couldn’t transfer the physical substrate implementing the “software” of our mind to another body, provided the other body were equipped to receive such a physical substrate. But this doesn’t have quite the same advantage as beaming oneself to the other side of Earth, or Andromeda for that matter, at the speed of light.

But to transfer a given WBE to another mental substrate without incurring phenomenal discontinuity may very well involve a second gradual integration procedure, in addition to the one the WBE initially underwent (assuming it isn’t a product of destructive uploading). And indeed, this would be more properly thought of in the context of a new substrate being gradually integrated with the WBE’s existing substrate, rather than the other way around (i.e., portions of the WBE’s substrate being gradually integrated with an external substrate.) It is likely to be much easier to simply transfer a given physical/mental substrate to another body, or to bypass this need altogether by actuating bodies via tele-operation instead.

In summary, what is sought is substrate-independence for mind in general, and not for a specific mind in particular (at least not without a gradual integration procedure, like the type underlying the notion of gradual uploading, so as to transfer such a mind to a new substrate without causing phenomenal discontinuity).

The Term “Uploading” Misconstrues More Than It Clarifies

The term “Mind Uploading” has some drawbacks and creates common initial misconceptions. It is based off terminology originating from the context of conventional, contemporary computers – which may lead to the initial impression that we are talking about uploading a given mind into a desktop PC, to be run in the manner that Microsoft Word is run. This makes the notion of WBE more fantastic and incredible – and thus improbable – than it actually is. I don’t think anyone seriously speculating about WBE would entertain such a notion.

Another potential misinterpretation particularly likely to result from the term “Mind Uploading” is that we seek to upload a mind into a computer – as though it were nothing more than a simple file transfer. This, again, connotes modern paradigms of computation and communications technology that are unlikely to be used for WBE. It also creates the connotation of putting the mind into a computer – whereas a more accurate connotation, at least as far as gradual uploading as opposed to destructive uploading is concerned, would be bringing the computer gradually into the biological mind.

It is easy to see why the term initially came into use. The notion of destructive uploading was the first embodiment of the concept. The notion of gradual uploading so as to mitigate the philosophical problems pertaining to how much a copy can be considered the same person as the original, especially in contexts where they are both simultaneously existent, came afterward. In the context of destructive uploading, it makes more connotative sense to think of concepts like uploading and file transfer.

But in the notion of gradual uploading, portions of the biological brain – most commonly single neurons, as in Robert A. Freitas’s and Ray Kurzweil’s versions of gradual uploading – are replaced with in-vivo computational substrate, to be placed where the neuron it is replacing was located. Such a computational substrate would be operatively connected to electrical or electrochemical sensors (to translate the biochemical or, more generally, biophysical output of adjacent neurons into computational input that can be used by the computational emulation) and electrical or electrochemical actuators (to likewise translate computational output of the emulation into biophysical input that can be used by adjacent biological neurons). It is possible to have this computational emulation reside in a physical substrate existing outside of the biological brain, connected to in-vivo biophysical sensors and actuators via wireless communication (i.e., communicating via electromagnetic signal), but this simply introduces a potential lag-time that may then have to be overcome by faster sensors, faster actuators, or a faster emulation. It is likely that the lag-time would be negligible, especially if it was located in a convenient module external to the body but “on it” at all times, to minimize transmission delays increasing as one gets farther away from such an external computational device. This would also likely necessitate additional computation to model the necessary changes to transmission speed in response to how far away the person is.  Otherwise, signals that are meant to arrive at a given time could arrive too soon or too late, thereby disrupting functionality. However, placing the computational substrate in vivo obviates these potential logistical obstacles.

This notion is I think not brought into the discussion enough. It is an intuitively obvious notion if you’ve thought a great deal about Substrate-Independen -Minds and frequented discussions on Mind Uploading. But to a newcomer who has heard the term Gradual Uploading for the first time, it is all too easy to think “yes, but then one emulated neuron would exist on a computer, and the original biological neuron would still be in the brain. So once you’ve gradually emulated all these neurons, you have an emulation on a computer, and the original biological brain, still as separate physical entities. Then you have an original and the copy – so where does the gradual in Gradual Uploading come in? How is this any different than destructive uploading? At the end of the day you still have a copy and an original as separate entities.”

This seeming impasse is I think enough to make the notion of Gradual Uploading seem at least intuitively or initially incredible and infeasible before people take the time to read the literature and discover how gradual uploading could actually be achieved (i.e., wherein each emulated neuron is connected to biophysical sensors and actuators to facilitate operational connection and causal interaction with existing in-vivo biological neurons) without fatally tripping upon such seeming logistical impasses, as in the example above. The connotations created by the term I think to some extent make it seem so fantastic (as in the overly simplified misinterpretations considered above) that people write off the possibility before delving deep enough into the literature and discussion to actually ascertain the possibility with any rigor.

The Computability of the Mind

Another common misconception is that the feasibility of Mind Uploading is based upon the notion that the brain is a computer or operates like a computer. The worst version of this misinterpretation that I’ve come across is that proponents and supporters of Mind Uploading are claiming that the mind is similar in operation current and conventional paradigms of computer.

Before I elaborate why this is wrong, I’d like to point out a particularly harmful sentiment that can result from this notion. It makes the concept of Mind Uploading seem dehumanizing, because conventional computers don’t display anything like intelligence or emotion. This makes people conflate the possible behaviors of future computers with the behaviors of current computers. Obviously computers don’t feel happiness or love, and so to say that the brain is like a computer is a farcical claim.

Machines don’t have to be as simple or as un-adaptable and invariant as the are today. The universe itself is a machine. In other words, either everything is a machine or nothing is.

This misunderstanding also makes people think that advocates and supporters of Mind Uploading are claiming that the mind is reducible to basic or simple autonomous operations, like cogs in a machine, which constitutes for many people a seeming affront to our privileged place in the universe as humans, in general, and to our culturally ingrained notions of human dignity being inextricably tied to physical irreducibility, in particular. The intuitive notions of human dignity and the ontologically privileged nature of humanity have yet to catch up with physicalism and scientific materialism (a.k.a. metaphysical naturalism). It is not the proponents of Mind Uploading that are raising these claims, but science itself – and for hundreds of years, I might add. Man’s privileged and physically irreducible ontological status has become more and more undermined throughout history since at least as far back as the Darwin’s theory of Evolution, which brought the notion of the past and future phenotypic evolution of humanity into scientific plausibility for the first time.

It is also seemingly disenfranchising to many people, in that notions of human free will and autonomy seem to be challenged by physical reductionism and determinism – perhaps because many people’s notions of free will are still associated with a non-physical, untouchably metaphysical human soul (i.e., mind-body dualism) which lies outside the purview of physical causality. To compare the brain to a “mindless machine” is still for many people disenfranchising to the extent that it questions the legitimacy of their metaphysically tied notions of free will.

Just because the sheer audacity of experience and the raucous beauty of feeling is ultimately reducible to physical and procedural operations (I hesitate to use the word “mechanisms” for its likewise misconnotative conceptual associations) does not take away from it. If it were the result of some untouchable metaphysical property, a sentiment that mind-body-dualism promulgated for quite some time, then there would be no way for us to understand it, to really appreciate it, and to change it (e.g., improve upon it) in any way. Physicalism and scientific materialism are needed if we are to ever see how it is done and to ever hope to change it for the better. Figuring out how things work is one of Man’s highest merits – and there is no reason Man’s urge to discover and determine the underlying causes of the world should not apply to his own self as well.

Moreover, the fact that experience, feeling, being, and mind result from the convergence of singly simple systems and processes makes the mind’s emergence from such simple convergence all the more astounding, amazing, and rare, not less! If the complexity and unpredictability of mind were the result of complex and unpredictable underlying causes (like the metaphysical notions of mind-body dualism connote), then the fact that mind turned out to be complex and unpredictable wouldn’t be much of a surprise. The simplicity of the mind’s underlying mechanisms makes the mind’s emergence all the more amazing, and should not take away from our human dignity but should instead raise it up to heights yet unheralded.

Now that we have addressed such potentially harmful second-order misinterpretations, we will address their root: the common misinterpretations likely to result from the phrase “the computability of the mind”. Not only does this phrase not say that the mind is similar in basic operation to conventional paradigms of computation – as though a neuron were comparable to a logic gate or transistor – but neither does it necessarily make the more credible claim that the mind is like a computer in general. This makes the notion of Mind-Uploading seem dubious because it conflates two different types of physical systems – computers and the brain.

The kidney is just as computable as the brain. That is to say that the computability of mind denotes the ability to make predictively accurate computational models (i.e., simulations and emulations) of biological systems like the brain, and is not dependent on anything like a fundamental operational similarity between biological brains and digital computers. We can make computational models of a given physical system, feed it some typical inputs, and get a resulting output that approximately matches the real-world (i.e., physical) output of such a system.

The computability of the mind has very little to do with the mind acting as or operating like a computer, and much, much more to do with the fact that we can build predictively accurate computational models of physical systems in general. This also, advantageously, negates and obviates many of the seemingly dehumanizing and indignifying connotations identified above that often result from the claim that the brain is like a machine or like a computer. It is not that the brain is like a computer – it is just that computers are capable of predictively modeling the physical systems of the universe itself.

We Want Not To Become Machines, But To Keep Up With Them!

Too often is uploading portrayed as the means to superhuman speed of thought or to transcending our humanity. It is not that we want to become less human, or to become like a machine. For most Transhumanists and indeed most proponents of Mind Uploading and Substrate-Independent Minds, meat is machinery anyways. In other words there is no real (i.e., legitimate) ontological distinction between human minds and machines to begin with. Too often is uploading seen as the desire for superhuman abilities. Too often is it seen as a bonus, nice but ultimately unnecessary.

I vehemently disagree. Uploading has been from the start for me (and I think for many other proponents and supporters of Mind Uploading) a means of life extension, of deferring and ultimately defeating untimely, involuntary death, as opposed to an ultimately unnecessary means to better powers, a more privileged position relative to the rest of humanity, or to eschewing our humanity in a fit of contempt of the flesh. We do not want to turn ourselves into Artificial Intelligence, which is a somewhat perverse and burlesque caricature that is associated with Mind Uploading far too often.

The notion of gradual uploading is implicitly a means of life extension. Gradual uploading will be significantly harder to accomplish than destructive uploading. It requires a host of technologies and methodologies – brain-scanning, in-vivo locomotive systems such as but not limited to nanotechnology, or else extremely robust biotechnology – and a host of precautions to prevent causing phenomenal discontinuity, such as enabling each non-biological functional replacement time to causally interact with adjacent biological components before the next biological component that it causally interacts with is likewise replaced. Gradual uploading is a much harder feat than destructive uploading, and the only advantage it has over destructive uploading is preserving the phenomenal continuity of a single specific person. In this way it is implicitly a means of life extension, rather than a means to the creation of AGI, because its only benefit is the preservation and continuation of a single, specific human life, and that benefit entails a host of added precautions and additional necessitated technological and methodological infrastructures.

If we didn’t have to fear the creation of recursively self-improving AI, biased towards being likely to recursively self-modify at a rate faster than humans are likely to (or indeed, are able to safely – that is, gradually enough to prevent phenomenal discontinuity), then I would favor biotechnological methods of achieving indefinite lifespans over gradual uploading. But with the way things are, I am an advocate of gradual Mind Uploading first and foremost because I think it may prove necessary to prevent humanity from being left behind by recursively self-modifying superintelligences. I hope that it ultimately will not prove necessary – but at the current time I feel that it is somewhat likely.

Most people who wish to implement or accelerate an intelligence explosion a la I.J. Good, and more recently Vernor Vinge and Ray Kurzweil, wish to do so because they feel that such a recursively self-modifying superintelligence (RSMSI) could essentially solve all of humanity’s problems – disease, death, scarcity, existential insecurity. I think that the potential benefits of creating a RSMSI are superseded by the drastic increase in existential risk it would entail in making any one entity superintelligent relative to humanity. The old God of yore is finally going out of fashion, one and a quarter centuries late to his own eulogy. Let’s please not make another one, now with a little reality under his belt this time around.

Intelligence is a far greater source of existential and global catastrophic risk than any technology that could be wielded by such an intelligence (except, of course, for technologies that would allow an intelligence to increase its own intelligence). Intelligence can invent new technologies and conceive of ways to counteract any defense systems we put in place to protect against the destructive potentials of any given technology. A superintelligence is far more dangerous than rogue nanotech (i.e., grey-goo) or bioweapons. When intelligence comes into play, then all bets are off. I think culture exemplifies this prominently enough. Moreover, for the first time in history the technological solutions to these problems – death, disease, scarcity – are on the conceptual horizon. We can fix these problems ourselves, without creating an effective God relative to Man and incurring the extreme potential for complete human extinction that such a relative superintelligence would entail.

Thus uploading constitutes one of the means by which humanity can choose, volitionally, to stay on the leading edge of change, discovery, invention, and novelty, if the creation of a RSMSI is indeed imminent. It is not that we wish to become machines and eschew our humanity – rather the loss of autonomy and freedom inherent in the creation of a relative superintelligence is antithetical to the defining features of humanity. In order to preserve the uniquely human thrust toward greater self-determination in the face of such a RSMSI, or at least be given the choice of doing so, we may require the ability to gradually upload so as to stay on equal footing in terms of speed of thought and general level of intelligence (which is roughly correlative with the capacity to affect change in the world and thus to determine its determining circumstances and conditions as well).

In a perfect world we wouldn’t need to take the chance of phenomenal discontinuity inherent in gradual uploading. In gradual uploading there is always a chance, no matter how small, that we will come out the other side of the procedure as a different (i.e., phenomenally distinct) person. We can seek to minimize the chances of that outcome by extending the degree of graduality with which we gradually replace the material constituents of the mind, and by minimizing the scale at which we gradually replace those material constituents (i.e., gradual substrate replacement one ion-channel at a time would be likelier to ensure the preservation of phenomenal continuity than gradual substrate replacement neuron by neuron would be). But there is always a chance.

This is why biotechnological means of indefinite lifespans have an immediate advantage over uploading, and why if non-human RSMSI were not a worry, I would favor biotechnological methods of indefinite lifespans over Mind Uploading. But this isn’t the case; rogue RSMSI are a potential problem, and so the ability to secure our own autonomy in the face of a rising RSMSI may necessitate advocating Mind Uploading over biotechnological methods of indefinite lifespans.

Mind Uploading has some ancillary benefits over biotechnological means of indefinite lifespans as well, however. If functional equivalence is validated (i.e., if it is validated that the basic approach works), mitigating existing sources of damage becomes categorically easier. In physical embodiment, repairing structural, connectional, or procedural sub-systems in the body requires (1) a means of determining the source of damage and (2) a host of technologies and corresponding methodologies to enter the body and make physical changes to negate or otherwise obviate the structural, connectional, or procedural source of such damages, and then exit the body without damaging or causing dysfunction to other systems in the process. Both of these requirements become much easier in the virtual embodiment of whole-brain emulation.

First, looking toward requirement (2), we do not need to actually design any technologies and methodologies for entering and leaving the system without damage or dysfunction or for actually implementing physical changes leading to the remediation of the sources of damage. In virtual embodiment this requires nothing more than rewriting information. Since in the case of WBE we have the capacity to rewrite information as easily as it was written in the first place, while we would still need to know what changes to make (which is really the hard part in this case), actually implementing those changes is as easy as rewriting a word file. There is no categorical difference, since it is information, and we would already have a means of rewriting information.

Looking toward requirement (1), actually elucidating the structural, connectional or procedural sources of damage and/or dysfunction, we see that virtual embodiment makes this much easier as well. In physical embodiment we would need to make changes to the system in order to determine the source of the damage. In virtual embodiment we could run a section of emulation for a given amount of time, change or eliminate a given informational variable (i.e. structure, component, etc.) and see how this affects the emergent system-state of the emulation instance.

Iteratively doing this to different components and different sequences of components, in trial-and-error fashion, should lead to the elucidation of the structural, connectional or procedural sources of damage and dysfunction. The fact that an emulation can be run faster (thus accelerating this iterative change-and-check procedure) and that we can “rewind” or “play back” an instance of emulation time exactly as it occurred initially means that noise (i.e., sources of error) from natural systemic state-changes would not affect the results of this procedure, whereas in physicality systems and structures are always changing, which constitutes a source of experimental noise. The conditions of the experiment would be exactly the same in every iteration of this change-and-check procedure. Moreover, the ability to arbitrarily speed up and slow down the emulation will aid in our detecting and locating the emergent changes caused by changing or eliminating a given microscale component, structure, or process.

Thus the process of finding the sources of damage correlative with disease and aging (especially insofar as the brain is concerned) could be greatly improved through the process of uploading. Moreover, WBE should accelerate the technological and methodological development of the computational emulation of biological systems in general, meaning that it would be possible to use such procedures to detect the structural, connectional, and procedural sources of age-related damage and systemic dysfunction in the body itself, as opposed to just the brain, as well.

Note that this iterative change-and-check procedure would be just as possible via destructive uploading as it would with gradual uploading. Moreover, in terms of people actually instantiated as whole-brain emulations, actually remediating those structural, connectional, and/or procedural sources of damage as it pertains to WBEs is much easier than physically-embodied humans. Anecdotally, if being able to distinguish among the homeostatic, regulatory, and metabolic structures and processes in the brain from the computational or signal-processing structures and processes in the brain is a requirement for uploading (which I don’t think it necessarily is, although I do think that such a distinction would decrease the ultimate computational intensity and thus computational requirements of uploading, thereby allowing it to be implemented sooner and have wider availability), then this iterative change-and-check procedure could also be used to accelerate the elucidation of such a distinction as well, for the same reasons that it could accelerate the elucidation of structural, connectional, and procedural sources of age-related systemic damage and dysfunction.

Lastly, while uploading (particularly instances in which a single entity or small group of entities is uploaded prior to the rest of humanity – i.e. not a maximally distributed intelligence explosion) itself constitutes a source of existential risk, it also constitutes a means of mitigating existential risk as well. Currently we stand on the surface of the earth, naked to whatever might lurk in the deep night of space. We have not been watching the sky for long enough to know with any certainty that some unforeseen cosmic process could not come along to wipe us out at any time. Uploading would allow at least a small portion of humanity to live virtually on a computational substrate located deep underground, away from the surface of the earth and its inherent dangers, thus preserving the future human heritage should an extinction event befall humanity. Uploading would also prevent the danger of being physically killed by some accident of physicality, like being hit by a bus or struck by lightning.

Uploading is also the most resource-efficient means of life-extension on the table, because virtual embodiment not only essentially negates the need for many physical resources (instead necessitating one, namely energy – and increasing computational price-performance means that just how much a given amount of energy can do is continually increasing).

It also mitigates the most pressing ethical problem of indefinite lifespans – overpopulation. In virtual embodiment, overpopulation ceases to be an issue almost ipso facto. I agree with John Smart’s STEM compression hypothesis – that in the long run the advantages proffered by virtual embodiment will make choosing it over physical embodiment, in the long run at least, an obvious choice for most civilizations, and I think it will be the volitional choice for most future persons. It is safer, more resource-efficient (and thus more ethical, if one thinks that forestalling future births in order to maintain existing life is unethical) and the more advantageous choice. We will not need to say: migrate into virtuality if you want another physically embodied child. Most people will make the choice to go VR themselves simply due to the numerous advantages and the lack of any experiential incomparabilities (i.e., modalities of experience possible in physicality but not possible in VR).

So in summary, yes, Mind Uploading (especially gradual uploading) is more a means of life-extension than a means to arbitrarily greater speed of thought, intelligence or power (i.e., capacity to affect change in the world). We do not seek to become machines, only to retain the capability of choosing to remain on equal footing with them if the creation of RSMSI is indeed imminent. There is no other reason to increase our collective speed of thought, and to do so would be arbitrary – unless we expected to be unable to prevent the physical end of the universe, in which case it would increase the ultimate amount of time and number of lives that could be instantiated in the time we have left.

The fallibility of many of these misconceptions may be glaringly obvious, especially to those readers familiar with Mind Uploading as notion and Substrate-Independent Minds and/or Whole-Brain Emulation as disciplines. I may be to some extent preaching to the choir in these cases. But I find many of these misinterpretations far too predominant and recurrent to be left alone.

Franco Cortese is an editor for Transhumanity.net, as well as one of its most frequent contributors.  He has also published articles and essays on Immortal Life and The Rational Argumentator. He contributed 4 essays and 7 debate responses to the digital anthology Human Destiny is to Eliminate Death: Essays, Rants and Arguments About Immortality.

Franco is an Advisor for Lifeboat Foundation (on its Futurists Board and its Life Extension Board) and contributes regularly to its blog.

Squishy Machines: Bio-Cybernetic Neuron Hybrids – Article by Franco Cortese

Squishy Machines: Bio-Cybernetic Neuron Hybrids – Article by Franco Cortese

The New Renaissance Hat
Franco Cortese
May 25, 2013
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This essay is the eighth chapter in Franco Cortese’s forthcoming e-book, I Shall Not Go Quietly Into That Good Night!: My Quest to Cure Death, published by the Center for Transhumanity. The first seven chapters were previously published on The Rational Argumentator under the following titles:
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By 2009 I felt the major classes of physicalist-functionalist replication approaches to be largely developed, producing now only potential minor variations in approach and procedure. These developments consisted of contingency plans in the case that some aspect of neuronal operation couldn’t be replicated with alternate, non-biological physical systems and processes, based around the goal of maintaining those biological (or otherwise organic) systems and processes artificially and of integrating them with the processes that could be reproduced artificially.

2009 also saw further developments in the computational approach, where I conceptualized a new sub-division in the larger class of the informational-functionalist (i.e., computational, which encompasses both simulation and emulation) replication approach, which is detailed in the next chapter.

Developments in the Physicalist Approach

During this time I explored mainly varieties of the cybernetic-physical functionalist approach. This involved the use of replicatory units that preserve certain biological aspects of the neuron while replacing certain others with functionalist replacements, and other NRUs that preserved alternate biological aspects of the neuron while replacing different aspects with functional replacements. The reasoning behind this approach was twofold. The first was that there was a chance, no matter how small, that we might fail to sufficiently replicate some relevant aspect(s) of the neuron either computationally or physically by failing to understand the underlying principles of that particular sub-process/aspect. The second was to have an approach that would work in the event that there was some material aspect that couldn’t be sufficiently replicated via non-biological physically embodied systems (i.e., the normative physical-functionalist approach).

However, these varieties were conceived of in case we couldn’t replicate certain components successfully (i.e., without functional divergence). The chances of preserving subjective-continuity in such circumstances are increased by the number of varieties we have for this class of model (i.e., different arrangements of mechanical replacement components and biological components), because we don’t know which we would fail to functionally replicate.

This class of physical-functionalist model can be usefully considered as electromechanical-biological hybrids, wherein the receptors (i.e., transporter proteins) on the post-synaptic membrane are integrated with the artificial membrane and in coexistence with artificial ion-channels, or wherein the biological membrane is retained while the receptor and ion-channels are replaced with functional equivalents instead. The biological components would be extracted from the existing biological neurons and reintegrated with the artificial membrane. Otherwise they would have to be synthesized via electromechanical systems, such as, but not limited to, the use of chemical stores of amino-acids released in specific sequences to facilitate in vivo protein folding and synthesis, which would then be transported to and integrated with the artificial membrane. This is better than providing stores of pre-synthesized proteins, due to more complexities in storing synthesized proteins without decay or functional degradation over storage-time, and in restoring them from their “stored”, inactive state to a functionally-active state when they were ready for use.

During this time I also explored the possibility of using the neuron’s existing protein-synthesis systems to facilitate the construction and gradual integration of the artificial sections with the existing lipid bilayer membrane. Work in synthetic biology allows us to use viral gene vectors to replace a given cell’s constituent genome—and consequently allowing us to make it manufacture various non-organic substances in replacement of the substances created via its normative protein-synthesis. We could use such techniques to replace the existing protein-synthesis instructions with ones that manufacture and integrate the molecular materials constituting the artificial membrane sections and artificial ion-channels and ion-pumps. Indeed, it may even be a functional necessity to gradually replace a given neuron’s protein-synthesis machinery with protein-synthesis-based machinery for the replacement, integration and maintenance of the non-biological sections’ material, because otherwise those parts of the neuron would still be trying to rebuild each section of lipid bilayer membrane we iteratively remove and replace. This could be problematic, and so for successful gradual replacement of single neurons, a means of gradually switching off and/or replacing portions of the cell’s protein-synthesis systems may be required.

Franco Cortese is an editor for Transhumanity.net, as well as one of its most frequent contributors.  He has also published articles and essays on Immortal Life and The Rational Argumentator. He contributed 4 essays and 7 debate responses to the digital anthology Human Destiny is to Eliminate Death: Essays, Rants and Arguments About Immortality.

Franco is an Advisor for Lifeboat Foundation (on its Futurists Board and its Life Extension Board) and contributes regularly to its blog.

Concepts for Functional Replication of Biological Neurons – Article by Franco Cortese

Concepts for Functional Replication of Biological Neurons – Article by Franco Cortese

The New Renaissance Hat
Franco Cortese
May 18, 2013
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This essay is the third chapter in Franco Cortese’s forthcoming e-book, I Shall Not Go Quietly Into That Good Night!: My Quest to Cure Death, published by the Center for Transhumanity. The first two chapters were previously published on The Rational Argumentator as “The Moral Imperative and Technical Feasibility of Defeating Death” and “Immortality: Material or Ethereal? Nanotech Does Both!“.
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The simplest approach to the functional replication of biological neurons I conceived of during this period involved what is normally called a “black-box” model of a neuron. This was already a concept in the wider brain-emulation community, but I was yet to find out about it. This is even simpler than the mathematically weighted Artificial Neurons discussed in the previous chapter. Rather than emulating or simulating the behavior of a neuron, (i.e, using actual computational—or more generally signal—processing) we (1) determine the range of input values that a neuron responds to, (2) stimulate the neuron at each interval (the number of intervals depending on the precision of the stimulus) within that input-range, and (3) record the corresponding range of outputs.

This reduces the neuron to essentially a look-up-table (or, more formally, an associative array). The input ranges I originally considered (in 2007) consisted of a range of electrical potentials, but later (in 2008) were developed to include different cumulative organizations of specific voltage values (i.e., some inputs activated and others not) and finally the chemical input and outputs of neurons. The black-box approach was eventually seen as being applied to the sub-neuron scale—e.g., to sections of the cellular membrane. This creates a greater degree of functional precision, bringing the functional modality of the black-box NRU-class in greater accordance with the functional modality of biological neurons. (I.e., it is closer to biological neurons because they do in fact process multiple inputs separately, rather than singular cumulative sums at once, as in the previous versions of the black-box approach.) We would also have a higher degree of variability for a given quantity of inputs.

I soon chanced upon literature dealing with MEMS (micro-electro-mechanical systems) and NEMS (nano-electro-mechanical systems), which eventually led me to nanotechnology and its use in nanosurgery in particular. I saw nanotechnology as the preferred technological infrastructure regardless of the approach used; its physical nature (i.e., operational and functional modalities) could facilitate the electrical and chemical processes of the neuron if the physicalist-functionalist (i.e., physically embodied or ‘prosthetic’) approach proved either preferable or required, while the computation required for its normative functioning (regardless of its particular application) assured that it could facilitate the informationalist-functionalist (i.e., computational emulation or simulation) of neurons if that approach proved preferable. This was true of MEMS as well, with the sole exception of not being able to directly synthesize neurotransmitters via mechanosynthesis, instead being limited in this regard to the release of pre-synthesized biochemical inventories. Thus I felt that I was able to work on conceptual development of the methodological and technological infrastructure underlying both (or at least variations to the existing operational modalities of MEMS and NEMS so as to make them suitable for their intended use), without having to definitively choose one technological/methodological infrastructure over the other. Moreover, there could be processes that are reducible to computation, yet still fail to be included in a computational emulation due to our simply failing to discover the principles underlying them. The prosthetic approach had the potential of replicating this aspect by integrating such a process, as it exists in the biological environment, into its own physical operation, and perform iterative maintenance or replacement of the biological process, until such a time as to be able to discover the underlying principles of those processes (which is a prerequisite for discovering how they contribute to the emergent computation occurring in the neuron) and thus for their inclusion in the informationalist-functionalist approach.

Also, I had by this time come across the existing approaches to Mind-Uploading and Whole-Brain Emulation (WBE), including Randal Koene’s minduploading.org, and realized that the notion of immortality through gradually replacing biological neurons with functional equivalents wasn’t strictly my own. I hadn’t yet come across Kurzweil’s thinking in regard to gradual uploading described in The Singularity is Near (where he suggests a similarly nanotechnological approach), and so felt that there was a gap in the extant literature in regard to how the emulated neurons or neural networks were to communicate with existing biological neurons (which is an essential requirement of gradual uploading and thus of any approach meant to facilitate subjective-continuity through substrate replacement). Thus my perceived role changed from the father of this concept to filling in the gaps and inconsistencies in the already-extant approach and in further developing it past its present state. This is another aspect informing my choice to work on and further varietize both the computational and physical-prosthetic approach—because this, along with the artificial-biological neural communication problem, was what I perceived as remaining to be done after discovering WBE.

The anticipated use of MEMS and NEMS in emulating the physical processes of the neurons included first simply electrical potentials, but eventually developed to include the chemical aspects of the neuron as well, in tandem with my increasing understanding of neuroscience. I had by this time come across Drexler’s Engines of Creation, which was my first introduction to antecedent proposals for immortality—specifically his notion of iterative cellular upkeep and repair performed by nanobots. I applied his concept of mechanosynthesis to the NRUs to facilitate the artificial synthesis of neurotransmitters. I eventually realized that the use of pre-synthesized chemical stores of neurotransmitters was a simpler approach that could be implemented via MEMS, thus being more inclusive for not necessitating nanotechnology as a required technological infrastructure. I also soon realized that we could eliminate the need for neurotransmitters completely by recording how specific neurotransmitters affect the nature of membrane-depolarization at the post-synaptic membrane and subsequently encoding this into the post-synaptic NRU (i.e., length and degree of depolarization or hyperpolarization, and possibly the diameter of ion-channels or differential opening of ion-channels—that is, some and not others) and assigning a discrete voltage to each possible neurotransmitter (or emergent pattern of neurotransmitters; salient variables include type, quantity and relative location) such that transmitting that voltage makes the post-synaptic NRU’s controlling-circuit implement the membrane-polarization changes (via changing the number of open artificial-ion-channels, or how long they remain open or closed, or their diameter/porosity) corresponding to the changes in biological post-synaptic membrane depolarization normally caused by that neurotransmitter.

In terms of the enhancement/self-modification side of things, I also realized during this period that mental augmentation (particularly the intensive integration of artificial-neural-networks with the existing brain) increases the efficacy of gradual uploading by decreasing the total portion of your brain occupied by the biological region being replaced—thus effectively making that portion’s temporary operational disconnection from the rest of the brain more negligible to concerns of subjective-continuity.

While I was thinking of the societal implications of self-modification and self-modulation in general, I wasn’t really consciously trying to do active conceptual work (e.g., working on designs for pragmatic technologies and methodologies as I was with limitless-longevity) on this side of the project due to seeing the end of death as being a much more pressing moral imperative than increasing our degree of self-determination. The 100,000 unprecedented calamities that befall humanity every day cannot wait; for these dying fires it is now or neverness.

Virtual Verification Experiments

The various alternative approaches to gradual substrate-replacement were meant to be alternative designs contingent upon various premises for what was needed to replicate functionality while retaining subjective-continuity through gradual replacement. I saw the various embodiments as being narrowed down through empirical validation prior to any whole-brain replication experiments. However, I now see that multiple alternative approaches—based, for example, on computational emulation (informationalist-functionalist) and physical replication (physicalist-functionalist) (these are the two main approaches thus far discussed) would have concurrent appeal to different segments of the population. The physicalist-functionalist approach might appeal to wide numbers of people who, for one metaphysical prescription or another, don’t believe enough in the computational reducibility of mind to bet their lives on it.

These experiments originally consisted of applying sensors to a given biological neuron, and constructing NRUs based on a series of variations on the two main approaches, running each and looking for any functional divergence over time. This is essentially the same approach outlined in the WBE Roadmap, which I was yet to discover at this point, that suggests a validation approach involving experiments done on single neurons before moving on to the organismal emulation of increasingly complex species up to and including the human. My thinking in regard to these experiments evolved over the next few years to also include the some novel approaches that I don’t think have yet been discussed in communities interested in brain-emulation.

An equivalent physical or computational simulation of the biological neuron’s environment is required to verify functional equivalence, as otherwise we wouldn’t be able to distinguish between functional divergence due to an insufficient replication-approach/NRU-design and functional divergence due to difference in either input or operation between the model and the original (caused by insufficiently synchronizing the environmental parameters of the NRU and its corresponding original). Isolating these neurons from their organismal environment allows the necessary fidelity (and thus computational intensity) of the simulation to be minimized by reducing the number of environmental variables affecting the biological neuron during the span of the initial experiments. Moreover, even if this doesn’t give us a perfectly reliable model of the efficacy of functional replication given the amount of environmental variables one expects a neuron belonging to a full brain to have, it is a fair approximator. Some NRU designs might fail in a relatively simple neuronal environment and thus testing all NRU designs using a number of environmental variables similar to the biological brain might be unnecessary (and thus economically prohibitive) given its cost-benefit ratio. And since we need to isolate the neuron to perform any early non-whole-organism experiments (i.e., on individual neurons) at all, having precise control over the number and nature of environmental variables would be relatively easy, as this is already an important part of the methodology used for normative biological experimentation anyways—because lack of control over environmental variables makes for an inconsistent methodology and thus for unreliable data.

And as we increase to the whole-network and eventually organismal level, a similar reduction of the computational requirements of the NRU’s environmental simulation is possible by replacing the inputs or sensory mechanisms (from single photocell to whole organs) with VR-modulated input. The required complexity and thus computational intensity of a sensorially mediated environment can be vastly minimized if the normative sensory environment of the organism is supplanted with a much-simplified VR simulation.

Note that the efficacy of this approach in comparison with the first (reducing actual environmental variables) is hypothetically greater because going from simplified VR version to the original sensorial environment is a difference, not of category, but of degree. Thus a potentially fruitful variation on the first experiment (physical reduction of a biological neuron’s environmental variables) would be not the complete elimination of environmental variables, but rather decreasing the range or degree of deviation in each variable, including all the categories and just reducing their degree.

Anecdotally, one novel modification conceived during this period involves distributing sensors (operatively connected to the sensory areas of the CNS) in the brain itself, so that we can viscerally sense ourselves thinking—the notion of metasensation: a sensorial infinite regress caused by having sensors in the sensory modules of the CNS, essentially allowing one to sense oneself sensing oneself sensing.

Another is a seeming refigurement of David Pearce’s Hedonistic Imperative—namely, the use of active NRU modulation to negate the effects of cell (or, more generally, stimulus-response) desensitization—the fact that the more times we experience something, or indeed even think something, the more it decreases in intensity. I felt that this was what made some of us lose interest in our lovers and become bored by things we once enjoyed. If we were able to stop cell desensitization, we wouldn’t have to needlessly lose experiential amplitude for the things we love.

In the next chapter I will describe the work I did in the first months of 2008, during which I worked almost wholly on conceptual varieties of the physically embodied prosthetic (i.e., physical-functionalist) approach (particularly in gradually replacing subsections of individual neurons to increase how gradual the cumulative procedure is) for several reasons:

The original utility of ‘hedging our bets’ as discussed earlier—developing multiple approaches increases evolutionary diversity; thus, if one approach fails, we have other approaches to try.

I felt the computational side was already largely developed in the work done by others in Whole-Brain Emulation, and thus that I would be benefiting the larger objective of indefinite longevity more by focusing on those areas that were then comparatively less developed.

The perceived benefit of a new approach to subjective-continuity through a substrate-replacement procedure aiming to increase the likelihood of gradual uploading’s success by increasing the procedure’s cumulative degree of graduality. The approach was called Iterative Gradual Replacement and consisted of undergoing several gradual-replacement procedures, wherein the class of NRU used becomes progressively less similar to the operational modality of the original, biological neurons with each iteration; the greater the number of iterations used, the less discontinuous each replacement-phase is in relation to its preceding and succeeding phases. The most basic embodiment of this approach would involve gradual replacement with physical-functionalist (prosthetic) NRUs that in turn are then gradually replaced with informational-physicalist (computational/emulatory) NRUs. My qualms with this approach today stem from the observation that the operational modalities of the physically embodied NRUs seem as discontinuous in relation to the operational modalities of the computational NRUs as the operational modalities of the biological neurons does. The problem seems to result from the lack of an intermediary stage between physical embodiment and computational (or second-order) embodiment.

Franco Cortese is an editor for Transhumanity.net, as well as one of its most frequent contributors.  He has also published articles and essays on Immortal Life and The Rational Argumentator. He contributed 4 essays and 7 debate responses to the digital anthology Human Destiny is to Eliminate Death: Essays, Rants and Arguments About Immortality.

Franco is an Advisor for Lifeboat Foundation (on its Futurists Board and its Life Extension Board) and contributes regularly to its blog.

Bibliography

Embedded Processor. (2013). In Encyclopædia Britannica. Retrieved from http://www.britannica.com/EBchecked/topic/185535/embedded-processor

Jerome, P. (1980). Recording action potentials from cultured neurons with extracellular microcircuit electrodes. Journal or Neuroscience Methods, 2 (1), 19-31.

Wolf, W. & (March 2009). Cyber-physical Systems. In Embedded Computing. Retrieved February 28, 2013 from http://www.jiafuwan.net/download/cyber_physical_systems.pdf