President Obama disbanded the President’s Council on Bioethics after it questioned his policy on embryonic stem cell research. White House press officer Reid Cherlin said that this was because the Council favored discussion over developing a shared consensus. This column lists a number of problems with Obama’s decision, and with his position on the most controversial bioethical issue of our time.

Bioethics and the End of Discussion

In early June, President Obama disbanded the President’s Council on Bioethics. According to White House press officer Reid Cherlin, this was because the Council was designed by the Bush administration to be “a philosophically leaning advisory group” that favored discussion over developing a shared consensus. http://www.nytimes.com/2009/06/18/us/politics/18ethics.html?_r=2

Shared consensus? Like the shared consensus about the Mexico City policy, government funding of Embryonic Stem Cell Research for new lines, or taxpayer funded abortions? All this despite the fact that 51% of Americans consider themselves pro-life? By allowing publicly-funded Embryonic Stem Cell Research only on existing lines, President Bush made a decision that nobody was happy with, but at least it was an honest compromise, and given the principle of second effect, an ethically acceptable one.

President Obama will appoint a new bioethics commission, one with a new mandate and that “offers practical policy options,” Mr. Cherlin said.

Practical policy options? Like the ones likely to be given by Obama’s new authoritative committee to expediently promote the license to kill the most innocent and vulnerable? But that is only the start. As the baby boomers bankrupt Social Security, there will be a strong temptation to expand Obama’s mandate to include the aging “useless mouths”. Oregon and the Netherlands have already shown the way—after all, a suicide pill is much cheaper than palliative care, and it’s much more cost-effective to kill patients rather than care for them. (http://www.euthanasia.com/argumentsagainsteuthanasia.html)

Evan Rosa details many problems with Obama’s decision to disband the Council (http://www.cbc-network.org/research_display.php?id=388), but there are additional disturbing implications:

First, democracies are absolutely dependent on discussion. Dictators have always suppressed free discussion on “sensitive” subjects because it is the nature of evil to fear criticism. This has been true here in the United States, too—in the years leading up to the Civil War, Southern senators and representatives tried to squelch all discussion on slavery. Maybe their consciences bothered them.

Second, no matter how well-meaning the participants may be, consensus between metaphysically opposed parties is impossible in some matters (such as the humanity of a baby a few months before he or she is born, the existence of God, consequentialist vs. deontological reasoning, etc.). The only way to get “consensus” in such situations is by exercising the monopoly of force owned by the government.

Third, stopping government-sponsored discussion on bioethics sets a dangerous precedent for the ethics surrounding nanotechnology. There are numerous ethical issues that nanotechnology is raising, and will continue to raise, that desperately require significant amounts of detailed discussion and deep thinking.

Tyrants begin by marginalizing anyone who disagrees with them, calling them hate-mongering obstructionists (or worse). In addition, they will use governmental power to subdue any who dare oppose their policies.

The details of the dismissal of the Council clearly shows this tendency, though the Council members are not acting very subdued. As one of them supposedly put it, “Instead of meeting at seminars, now we’ll be meeting on Facebook.”

On March 9, Obama removed restrictions on federal funding for research on embryonic stem cell lines derived by means that destroy human embryos.

On March 25, ten out of the eighteen members of the Council questioned Obama’s policy (http://www.thehastingscenter.org/Bioethicsforum/Post.aspx?id=3298).

In the second week of June, Obama fired them all.

Could it be that Obama doesn’t want discussion? We can see what happens if someone gives him advice that he doesn’t want.

Oprah Winfrey’s favorite physician Dr. Mehmet Oz, told her and Michael Fox that “the stem cell debate is dead” because “the problem with embryonic stem cells is that [they are]… very hard to control, and they can become cancerous” (http://www.oprah.com/media/20090319-tows-dr-oz-brain). Besides, induced pluripotent cells can become embryonic, thereby negating the very difficult necessity of cloning.

So “harvesting” embryonic stem cells is not only ethically problematic (i.e. wrong), but it is also scientifically untenable. Obama supports it anyway.

Maybe he could fire Oprah.

Tihamer Toth-Fejel, MS
General Dynamics Advanced Information Systems
Michigan Research and Development Center

Artificial brain ’10 years away’

A detailed, functional artificial human brain can be built within the next 10 years, a leading scientist has claimed.

Henry Markram, director of the Blue Brain Project, has already simulated elements of a rat brain.

He told the TED Global conference in Oxford that a synthetic human brain would be of particular use finding treatments for mental illnesses.

Around two billion people are thought to suffer some kind of brain impairment, he said.

“It is not impossible to build a human brain and we can do it in 10 years,” he said.

“And if we do succeed, we will send a hologram to TED to talk.”

‘Shared fabric’

The Blue Brain project was launched in 2005 and aims to reverse engineer the mammalian brain from laboratory data.

In particular, his team has focused on the neocortical column — repetitive units of the mammalian brain known as the neocortex.

The team are trying to reverse engineer the brain

“It’s a new brain,” he explained. “The mammals needed it because they had to cope with parenthood, social interactions complex cognitive functions.

“It was so successful an evolution from mouse to man it expanded about a thousand fold in terms of the numbers of units to produce this almost frightening organ.”

And that evolution continues, he said. “It is evolving at an enormous speed.”

Over the last 15 years, Professor Markram and his team have picked apart the structure of the neocortical column.

“It’s a bit like going and cataloguing a bit of the rainforest — how may trees does it have, what shape are the trees, how many of each type of tree do we have, what is the position of the trees,” he said.

“But it is a bit more than cataloguing because you have to describe and discover all the rules of communication, the rules of connectivity.”

The project now has a software model of “tens of thousands” of neurons — each one of which is different — which has allowed them to digitally construct an artificial neocortical column.

Although each neuron is unique, the team has found the patterns of circuitry in different brains have common patterns.

“Even though your brain may be smaller, bigger, may have different morphologies of neurons — we do actually share the same fabric,” he said.

“And we think this is species specific, which could explain why we can’t communicate across species.”

World view

To make the model come alive, the team feeds the models and a few algorithms into a supercomputer.

“You need one laptop to do all the calculations for one neuron,” he said. “So you need ten thousand laptops.”

The research could give insights into brain disease

Instead, he uses an IBM Blue Gene machine with 10,000 processors.

Simulations have started to give the researchers clues about how the brain works.

For example, they can show the brain a picture — say, of a flower — and follow the electrical activity in the machine.

“You excite the system and it actually creates its own representation,” he said.

Ultimately, the aim would be to extract that representation and project it so that researchers could see directly how a brain perceives the world.

But as well as advancing neuroscience and philosophy, the Blue Brain project has other practical applications.

For example, by pooling all the world’s neuroscience data on animals — to create a “Noah’s Ark”, researchers may be able to build animal models.

“We cannot keep on doing animal experiments forever,” said Professor Markram.

It may also give researchers new insights into diseases of the brain.

“There are two billion people on the planet affected by mental disorder,” he told the audience.

The project may give insights into new treatments, he said.

The TED Global conference runs from 21 to 24 July in Oxford, UK.

New York, NY (PRWEB) July 17, 2009 — The fourth annual Singularity Summit, a conference devoted to the better understanding of increasing intelligence and accelerating change, will be held in New York on October 3–4 in Kaufmann Hall at the historic 92nd St Y. The Summit brings together a visionary community to further dialogue and action on complex, long-term issues that are transforming the world.

Participants will hear talks from cutting-edge researchers and network with strategic business leaders. The world’s most eminent experts on forecasting, venture capital, emerging technologies, consciousness and life extension will present their unique perspectives on the future and how to get there. “The Singularity Summit is the premier conference on the Singularity,” says Ray Kurzweil, inventor of the CCD flatbed scanner and author of The Singularity is Near. “As we get closer to the Singularity, each year’s conference is better than the last.”

The Singularity Summit has previously been held in the San Francisco Bay Area, where it has been featured in numerous publications including the front page of the San Francisco Chronicle. It is hosted by the Singularity Institute, a 501©(3) nonprofit devoted to studying the benefits and risks of advanced technologies.

Select Speakers

* Ray Kurzweil is the author of The Singularity is Near (2005) and co-founder of Singularity University, which is backed by Google and NASA. At the Singularity Summit, he will present his theories on accelerating technological change and the future of humanity.

* Dr. David Chalmers, director of the Centre for Consciousness at Australian National University and one of the world’s foremost philosophers, will discuss mind uploading — the possibility of transferring human consciousness onto a computer network.

* Dr. Ed Boyden is a joint professor of Biological Engineering and of Brain and Cognitive Sciences at MIT. Discover Magazine named him one of the 20 best brains under 40.

* Peter Thiel is the president of Clarium, seed investor in Facebook, managing partner of Founders Fund, and co-founder of PayPal.

* Dr. Aubrey de Grey is a biogerontologist and Director of Research at the SENS Foundation, which seeks to extend the human lifespan. He will present on the ethics of this proposition.

* Dr. Philip Tetlock is Professor of Organizational Behavior at the Haas School of Business, University of California, Berkeley, and author of Expert Political Judgement: How Good Is It?

* Dr. Jürgen Schmidhuber is co-director of the Dalle Molle Institute for Artificial Intelligence in Lugano, Switzerland. He will discuss the mathematical essence of beauty and creativity.

* Dr. Gary Marcus is director of the NYU Infant Language Learning Center, and professor of psychology at New York University and author of the book Kludge.

See the Singularity Summit website at http://www.singularitysummit.com/.

The Singularity Summit is hosted by the Singularity Institute for Artificial Intelligence.

Starting next week, MediaX is putting on an exciting series of courses in The Summer Institute at Wallenberg Hall, on Stanford’s campus.

Course titles that are still open are listed below, and you can register and see the full list here. See you there!

————–

July 20: Social Connectedness in Ambient Intelligent Environments, Clifford Nass and Boris deRuyter

July 23: Semantic Integration, Carl Hewitt

August 3–4: Social Media Collaboratory, Howard Rheingold

August 5–6: New Metrics for New Media: Analytics for Social Media and Virtual Worlds, Martha Russell and Marc Smith

August 7: Media and Management Bridges Between Heart and Head for Impact, Neerja Raman

August 10–11: Data Visualization: Theory and Practice, Jeff Heer, David Kasik and John Gerth

August 12: Technology Transfer for Silicon Valley Outposts, Jean Marc Frangos, Chuck House

August 12–14: Collaborative Visualization for Collective, Connective and Distributed Intelligence, Jeff Heer, Bonnie deVarco, Katy Borner

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In these financially difficult times many funding bodies have to prioritise projects based around long established hypotheses.   Projects involving new avenues of investigation can receive very positive comments by scientific reviewers, yet are rarely funded, as they almost always appear risky compared with projects largely confirming or expanding existing ideas.  Such conservative projects are almost guaranteed to produce useful data, though with modest impact.  This situation can mean that research proposals with the potential to transform our understanding of a disease and offer new approaches to its treatment never reach the threshold for funding and are not implemented, even though the potential and quality of the science is acknowledged by reviewers and funding panel.
 
It appears that our work examining a viral cause for Alzheimer’s disease is in this category.  Despite our publishing a large number of potentially very exciting papers on this topic, and despite our research projects being reviewed favourably by scientific referees, few funding panels are prepared to commit resources to fund our work, as by doing so they deny funding to other more straightforward, very low risk projects.
 
We are therefore actively seeking sponsorship for several projects of varying costs to investigate the interaction of virus and specific genetic factor, the pathways of viral damage in the brain, and the effects of antiviral agents. All the projects would provide significant evidence strengthening the case for trialling antiviral agents in Alzheimer’s disease.  
 
Antiviral agents would inhibit a likely major cause of the disease in contrast to current treatments, which merely inhibit the symptoms.
 
If any Lifeboat member knows of a company or individual that would be interested in sponsoring some of our research on Alzheimer’s disease then please contact me for further details.

Ruth Itzhaki

Contact details:

[email protected]

Faculty of Life Sciences, Moffat Building, The University of Manchester, Manchester M60 1QD, UK 

 
Further reading:
 
The Times, London

http://www.timesonline.co.uk/tol/news/uk/health/article5295794.ece

Journal of Pathology
http://www3.interscience.wiley.com/journal/121411445/abstract

The Lancet
http://www.thelancet.com/journals/lancet/article/PIIS0140&#4…5/abstract

I would gladly email any further information.

Interestingly, it appears that Turing’s fascination with this sub-discipline of biology most probably stemmed from the same source as the one that inspired his better known research: at that time all of these fields of knowledge were in a state of flux and development, and all posed challenging fundamental questions. Furthermore, in each of the three disciplines that engaged his interest, the matters to which he applied his uniquely creative vision were directly connected to central questions underlying these disciplines, and indeed to deeper and broader philosophical questions into the nature of humanity, intelligence and the role played by evolution in shaping who we are and how we shape our world.

Central to Turing’s biological work was his interest in mechanisms that shape the development of form and pattern in autonomous biological systems, and which underlie the patterns we see in nature (2), from animal coat markings to leaf arrangement patterns on plant stems (phyllotaxis). This topic of research, which he named “morphogenesis,” (3) had not been previously studied with modeling tools. This was a knowledge gap that beckoned Turing; particularly as such methods of research came naturally to him.

In addition to the diverse reasons that attracted him to the field of pattern formation, a major ulterior motive for his research had to do with a contentious subject which, astonishingly, is still highly controversial in some countries to this day. In studying pattern formation he was seeking to help invalidate the “argument from design” (4) concept, which we know today as the hypothesis of “Intelligent Design.”

Turing was intent on demonstrating that the laws of physics are sufficient to explain our observations in the natural world; or in other words, that our findings do not need an omnipotent creator to explain them. It is ironic that Turing, whose work played a central role in laying the groundwork for the creation of Artificial Intelligence (AI), took a clear stance against creationism. This is testament to his acceptance of scientific evidence and rigorous research over weak analogy.

Unfortunately, those who did not and will not accept Darwinian natural selection as the mechanism of evolution will not see anything compelling in Turing’s work on morphogenesis. To those individuals, the development of AI can be taken as “proof,” or a convincing analogy, of the necessity and presence of a creator, the argument being that the Creator created humanity, and humanity creates AI.

However, what the supporters of intelligent design do not acknowledge is that natural selection is itself precisely the cause underlying the development of both humanity and its AI progeny. Just as natural selection resulted in the phenomena that Turing sought to model in his work on morphogenesis (which brings about the propagation of successful traits through the development of biological form and pattern), it is also the driver for the development of intelligence. Itself generated via internalized neuronal selection mechanisms (5, 6), intelligence allows organisms to adapt to their environment continually during life.

Intelligence is the ultimate tool, the development of which allows organisms to survive; it enables them to learn, respond to their environment and adapt their behavior within their own lifetime. It is the fruit of the natural process that brings about successive development over time in organisms faced with scarcity of resources. Moreover, it now allows humans to defy generational selection and develop intelligences external to our own, making use of computational techniques, including some which utilize evolutionary mechanisms (7).

The eventual development of true AI will be a landmark in many ways, notably in that these intelligences will have the ability to alter their own circuits (their version of neurons), immediately and at will. While the human body is capable of some degree of non-developmental neuronal plasticity, this takes place slowly and control of the process is limited to indirect mechanisms (such as varied forms of learning or stimulation). In contrast, the high plasticity and directly controlled design and structure of AI software and hardware will render them well suited to altering themselves and hence to developing improved subsequent AI generations.

In addition to a jump in the degree of plasticity and its control, AIs will constitute a further step forward with regard to the speed at which beneficial information can be shared. In contrast to the exceedingly slow rate at which advantageous evolutionary adaptations were spread through the populations observed by Darwin (over several generations), the rapidly increasing rates of communication in current society result in successful “adaptations” (which we call science and technology) being distributed at ever-increasing speeds. This is, of course, the principal reason why information sharing is beneficial for humans – it allows us to better adapt to reality and harness the environment to our advantage. It seems reasonable to predict that ultimately the sharing of information in AI will be practically instantaneous.

It is difficult to speculate what a combination of such rapid communication and high plasticity combined with ever-increasing processing speeds will be like. The point at which self-improving AIs emerge has been termed a technological singularity (8).

Thus, in summary: evolution begets intelligence (via evolutionary neuronal selection mechanisms); human intelligence begets artificial intelligence (using, among others, evolutionary computation methods), which at increasing cycle speeds, leads to a technological singularity – a further big step up the evolutionary ladder.

Sadly, being considerably ahead of his time and living in an environment that castigated his lifestyle and drove him from his research, meant that Turing did not live to see the full extent of his work’s influence. While he did not survive to an age in which AIs became prevalent, he did fulfill his ambition by taking part in the defeat of argument from design in the scientific community, and witnessed Darwinian natural selection becoming widely accepted. The breadth of his vision, the insight he displayed, and his groundbreaking research clearly place Turing on an equal footing with the most celebrated scientists of the previous century.

Forming requires heavy high powered machinery to press metals into their final desired shapes. Cutting procedures, such as milling and lathing, also require large, heavy, complex machinery, but also waste tremendous amounts of material as large bulk shapes are cut away emerging the final part. Casting metal parts requires a complex mold construction and preparation procedures, not only does a negative mold of the final part need to be constructed, but the mold needs to be prepared, usually by coating in ceramic slurries, before the molten metal is applied. Unless thousands of parts are required, the molds are a waste of energy, resources, and effort. Joining is a flexible process, and usually achieved by welding or brazing and works by melting metal between two fixed parts in order to join them — but the fixed parts present the same manufacturing problems.

Ideally then, in any self sustaining structure, metal parts should be constructed only in the final desired shape but without the need of a mold and very limited need for cutting or joining. In a salient progressive step toward this necessary goal, NASA demonstrates the innovative Electron Beam Free Forming Fabrication (http://www.aeronautics.nasa.gov/electron_beam.htm) Process. A rapid metal fabrication process essentially it “prints” a complex three dimensional object by feeding a molten wire through a computer controlled gun, building the part, layer by layer, and adding metal only where you desire it. It requires no molds and little or no tooling, and material properties are similar to other forming techniques. The complexity of the part is limited only by the imagination of the programmer and the dexterity of the wire feed and heating device.

Electron beam freeform fabrication process in action

According to NASA materials research engineer Karen Taminger, who is involved in developing the EBF3 process, extensive simulations and modeling by NASA of long duration space flights found no discernable pattern to the types of parts which failed, but the mass of the failed parts remained remarkably consistent throughout the studies done. This is a favorable finding to in-situe parts manufacturing and because of this the EBF³ team at NASA has been developing a desktop version. Taminger writes:

“Electron beam freeform fabrication (EBF³) is a cross-cutting technology for producing structural metal parts…The promise of this technology extends far beyond its applicability to low-cost manufacturing and aircraft structural designs. EBF³ could provide a way for astronauts to fabricate structural spare parts and new tools aboard the International Space Station or on the surface of the moon or Mars”

NASA’s Langley group working on the EBF3 process took their prototype desktop model for a ride on the microgravity simulating NASA flight and found the process works just fine even in micro gravity, or even against gravity.

A structural metal part fabricated from EBF³

The advantages this system offers are significant. Near net shape parts can be manufactured, significantly reducing scrap parts. Unitized parts can be made — instead of multiple parts that need riveting or bolting, final complex integral structures can be made. An entire spacecraft frame could be ‘printed’ in one sitting. The process also creates minimal waste products and is highly energy and feed stock efficient, critical to self sustaining structures. Metals can be placed only where they are desired and the material and chemistry properties can be tailored through the structure. The technical seminar features a structure with a smooth transitional gradient from one alloy to another. Also, structures can be designed specifically for their intended purposes, without needing to be tailored to manufacturing process, for example, stiffening ridges can be curvilinear, in response to the applied forces, instead of typical grid patterns which facilitate easy conventional manufacturing techniques. Manufactures, such as Sciaky Inc, (http://www.sciaky.com/64.html) are all ready jumping on the process

In combination with similar 3D part ‘printing’ innovations in plastics and other materials, the required complexity for sustaining all the mechanical and structural components of a self sustaining structure is plummeting drastically. Isolated structures could survive on a feed stock of scrap that is perpetually recycled as worn parts are replaced by free form manufacturing and the old ones melted to make new feed stock. Space colonies could combine such manufacturing technologies and scrap feedstock with resource collection creating a viable minimal volume and energy consuming system that could perpetually repair the structure – or even build more. Technologies like these show that the atomic level control that nanotechnology manufacturing proposals offer are not necessary to create self sustaining structure, and that with minor developments of modern technology, self sustaining structures could be built and operated successfully.