Category Archives: human enhancement

Two approaches to memristors

Within one day of each other in October 2018, two different teams working on memristors with applications to neuroprosthetics and neuromorphic computing (brainlike computing) announced their results.

Russian team

An October 15, 2018 (?) Lobachevsky University press release (also published on October 15, 2018 on EurekAlert) describes a new approach to memristors,

Biological neurons are coupled unidirectionally through a special junction called a synapse. An electrical signal is transmitted along a neuron after some biochemical reactions initiate a chemical release to activate an adjacent neuron. These junctions are crucial for cognitive functions, such as perception, learning and memory.

A group of researchers from Lobachevsky University in Nizhny Novgorod investigates the dynamics of an individual memristive device when it receives a neuron-like signal as well as the dynamics of a network of analog electronic neurons connected by means of a memristive device. According to Svetlana Gerasimova, junior researcher at the Physics and Technology Research Institute and at the Neurotechnology Department of Lobachevsky University, this system simulates the interaction between synaptically coupled brain neurons while the memristive device imitates a neuron axon.

A memristive device is a physical model of Chua’s [Dr. Leon Chua, University of California at Berkeley; see my May 9, 2008 posting for a brief description Dr. Chua’s theory] memristor, which is an electric circuit element capable of changing its resistance depending on the electric signal received at the input. The device based on a Au/ZrO2(Y)/TiN/Ti structure demonstrates reproducible bipolar switching between the low and high resistance states. Resistive switching is determined by the oxidation and reduction of segments of conducting channels (filaments) in the oxide film when voltage with different polarity is applied to it. In the context of the present work, the ability of a memristive device to change conductivity under the action of pulsed signals makes it an almost ideal electronic analog of a synapse.

Lobachevsky University scientists and engineers supported by the Russian Science Foundation (project No.16-19-00144) have experimentally implemented and theoretically described the synaptic connection of neuron-like generators using the memristive interface and investigated the characteristics of this connection.

“Each neuron is implemented in the form of a pulse signal generator based on the FitzHugh-Nagumo model. This model provides a qualitative description of the main neurons’ characteristics: the presence of the excitation threshold, the presence of excitable and self-oscillatory regimes with the possibility of a changeover. At the initial time moment, the master generator is in the self-oscillatory mode, the slave generator is in the excitable mode, and the memristive device is used as a synapse. The signal from the master generator is conveyed to the input of the memristive device, the signal from the output of the memristive device is transmitted to the input of the slave generator via the loading resistance. When the memristive device switches from a high resistance to a low resistance state, the connection between the two neuron-like generators is established. The master generator goes into the oscillatory mode and the signals of the generators are synchronized. Different signal modulation mode synchronizations were demonstrated for the Au/ZrO2(Y)/TiN/Ti memristive device,” – says Svetlana Gerasimova.

UNN researchers believe that the next important stage in the development of neuromorphic systems based on memristive devices is to apply such systems in neuroprosthetics. Memristive systems will provide a highly efficient imitation of synaptic connection due to the stochastic nature of the memristive phenomenon and can be used to increase the flexibility of the connections for neuroprosthetic purposes. Lobachevsky University scientists have vast experience in the development of neurohybrid systems. In particular, a series of experiments was performed with the aim of connecting the FitzHugh-Nagumo oscillator with a biological object, a rat brain hippocampal slice. The signal from the electronic neuron generator was transmitted through the optic fiber communication channel to the bipolar electrode which stimulated Schaffer collaterals (axons of pyramidal neurons in the CA3 field) in the hippocampal slices. “We are going to combine our efforts in the design of artificial neuromorphic systems and our experience of working with living cells to improve flexibility of prosthetics,” concludes S. Gerasimova.

The results of this research were presented at the 38th International Conference on Nonlinear Dynamics (Dynamics Days Europe) at Loughborough University (Great Britain).

This diagram illustrates an aspect of the work,

Caption: Schematic of electronic neurons coupling via a memristive device. Credit: Lobachevsky University

US team

The American Institute of Physics (AIP) announced the publication of a ‘memristor paper’ by a team from the University of Southern California (USC) in an October 16, 2018 news item on,

Just like their biological counterparts, hardware that mimics the neural circuitry of the brain requires building blocks that can adjust how they synapse, with some connections strengthening at the expense of others. One such approach, called memristors, uses current resistance to store this information. New work looks to overcome reliability issues in these devices by scaling memristors to the atomic level.

An October 16, 2018 AIP news release (also on EurekAlert), which originated the news item, delves further into the particulars of this particular piece of memristor research,

A group of researchers demonstrated a new type of compound synapse that can achieve synaptic weight programming and conduct vector-matrix multiplication with significant advances over the current state of the art. Publishing its work in the Journal of Applied Physics, from AIP Publishing, the group’s compound synapse is constructed with atomically thin boron nitride memristors running in parallel to ensure efficiency and accuracy.

The article appears in a special topic section of the journal devoted to “New Physics and Materials for Neuromorphic Computation,” which highlights new developments in physical and materials science research that hold promise for developing the very large-scale, integrated “neuromorphic” systems of tomorrow that will carry computation beyond the limitations of current semiconductors today.

“There’s a lot of interest in using new types of materials for memristors,” said Ivan Sanchez Esqueda, an author on the paper. “What we’re showing is that filamentary devices can work well for neuromorphic computing applications, when constructed in new clever ways.”

Current memristor technology suffers from a wide variation in how signals are stored and read across devices, both for different types of memristors as well as different runs of the same memristor. To overcome this, the researchers ran several memristors in parallel. The combined output can achieve accuracies up to five times those of conventional devices, an advantage that compounds as devices become more complex.

The choice to go to the subnanometer level, Sanchez said, was born out of an interest to keep all of these parallel memristors energy-efficient. An array of the group’s memristors were found to be 10,000 times more energy-efficient than memristors currently available.

“It turns out if you start to increase the number of devices in parallel, you can see large benefits in accuracy while still conserving power,” Sanchez said. Sanchez said the team next looks to further showcase the potential of the compound synapses by demonstrating their use completing increasingly complex tasks, such as image and pattern recognition.

Here’s an image illustrating the parallel artificial synapses,

Caption: Hardware that mimics the neural circuitry of the brain requires building blocks that can adjust how they synapse. One such approach, called memristors, uses current resistance to store this information. New work looks to overcome reliability issues in these devices by scaling memristors to the atomic level. Researchers demonstrated a new type of compound synapse that can achieve synaptic weight programming and conduct vector-matrix multiplication with significant advances over the current state of the art. They discuss their work in this week’s Journal of Applied Physics. This image shows a conceptual schematic of the 3D implementation of compound synapses constructed with boron nitride oxide (BNOx) binary memristors, and the crossbar array with compound BNOx synapses for neuromorphic computing applications. Credit: Ivan Sanchez Esqueda

Here’s a link to and a citation for the paper,

Efficient learning and crossbar operations with atomically-thin 2-D material compound synapses by Ivan Sanchez Esqueda, Huan Zhao and Han Wang. The article will appear in the Journal of Applied Physics Oct. 16, 2018 (DOI: 10.1063/1.5042468).

This paper is behind a paywall.

*Title corrected from ‘Two approaches to memristors featuring’ to ‘Two approaches to memristors’ on May 31, 2019 at 1455 hours PDT.

Genes, intelligence, Chinese CRISPR (clustered regularly interspaced short palindromic repeats) babies, and other children

This started out as an update and now it’s something else. What follows is a brief introduction to the Chinese CRISPR twins; a brief examination of parents, children, and competitiveness; and, finally, a suggestion that genes may not be what we thought. I also include a discussion about how some think scientists should respond when they know beforehand that one of their kin is crossing an ethical line. Basically, this is a complex topic and I am attempting to interweave a number of competing lines of query into one narrative about human nature and the latest genetics obsession.

Introduction to the Chinese CRISPR twins

Back in November 2018 I covered the story about the Chinese scientist, He Jiankui , who had used CRISPR technology to edit genes in embryos that were subsequently implanted in a waiting mother (apparently there could be as many as eight mothers) with the babies being brought to term despite an international agreement (of sorts) not to do that kind of work. At this time, we know of the twins, Lulu and Nana but, by now, there may be more babies. (I have much more detail about the initial controversies in my November 28, 2018 posting.)

It seems the drama has yet to finish unfolding. There may be another consequence of He’s genetic tinkering.

Could the CRISPR babies, Lulu and Nana, have enhanced cognitive abilities?

Yes, according to Antonio Regalado’s February 21, 2019 article (behind a paywall) for MIT’s (Massachusetts Institute of Technology) Technology Review, those engineered babies may have enhanced abilities for learning and remembering.

For those of us who can’t get beyond the paywall, others have been successful. Josh Gabbatiss in his February 22, 2019 article for provides some detail,

The world’s first gene edited babies may have had their brains unintentionally altered – and perhaps cognitively enhanced – as a result of the controversial treatment undertaken by a team of Chinese scientists.

Dr He Jiankui and his team allegedly deleted a gene from a number of human embryos before implanting them in their mothers, a move greeted with horror by the global scientific community. The only known successful birth so far is the case of twin girls Nana and Lulu.

The now disgraced scientist claimed that he removed a gene called CCR5 [emphasis mine] from their embroyos in an effort to make the twins resistant to infection by HIV.

But another twist in the saga has now emerged after a new paper provided more evidence that the impact of CCR5 deletion reaches far beyond protection against dangerous viruses – people who naturally lack this gene appear to recover more quickly from strokes, and even go further in school. [emphasis mine]

Dr Alcino Silva, a neurobiologist at the University of California, Los Angeles, who helped identify this role for CCR5 said the work undertaken by Dr Jiankui likely did change the girls’ brains.

“The simplest interpretation is that those mutations will probably have an impact on cognitive function in the twins,” he told the MIT Technology Review.

The connection immediately raised concerns that the gene was targeted due to its known links with intelligence, which Dr Silva said was his immediate response when he heard the news.

… there is no evidence that this was Dr Jiankui’s goal and at a press conference organised after the initial news broke, he said he was aware of the work but was “against using genome editing for enhancement”.


Claire Maldarelli’s February 22, 2019 article for Popular Science provides more information about the CCR5 gene/protein (Note: Links have been removed),

CCR5 is a protein that sits on the surface of white blood cells, a major component of the human immune system. There, it allows HIV to enter and infect a cell. A chunk of the human population naturally carries a mutation that makes CCR5 nonfunctional (one study found that 10 percent of Europeans have this mutation), which often results in a smaller protein size and one that isn’t located on the outside of the cell, preventing HIV from ever entering and infecting the human immune system.

The goal of the Chinese researchers’ work, led by He Jiankui of the Southern University of Science and Technology located in Shenzhen, was to tweak the embryos’ genome to lack CCR5, ensuring the babies would be immune to HIV.

But genetics is rarely that simple.

In recent years, the CCR5 gene has been a target of ongoing research, and not just for its relationship to HIV. In an attempt to understand what influences memory formation and learning in the brain, a group of researchers at UCLA found that lowering the levels of CCR5 production enhanced both learning and memory formation. This connection led those researchers to think that CCR5 could be a good drug target for helping stroke victims recover: Relearning how to move, walk, and talk is a key component to stroke rehabilitation.

… promising research, but it begs the question: What does that mean for the babies who had their CCR5 genes edited via CRISPR prior to their birth? Researchers speculate that the alternation will have effects on the children’s cognitive functioning. …

John Loeffler’s February 22, 2019 article for notes that there are still many questions about He’s (scientist’s name) research including, did he (pronoun) do what he claimed? (Note: Links have been removed),

Considering that no one knows for sure whether He has actually done as he and his team claim, the swiftness of the condemnation of his work—unproven as it is—shows the sensitivity around this issue.

Whether He did in fact edit Lulu and Nana’s genes, it appears he didn’t intend to impact their cognitive capacities. According to MIT Technology Review, not a single researcher studying CCR5’s role in intelligence was contacted by He, even as other doctors and scientists were sought out for advice about his project.

This further adds to the alarm as there is every expectation that He should have known about the connection between CCR5 and cognition.

At a gathering of gene-editing researchers in Hong Kong two days after the birth of the potentially genetically-altered twins was announced, He was asked about the potential impact of erasing CCR5 from the twins DNA on their mental capacity.

He responded that he knew about the potential cognitive link shown in Silva’s 2016 research. “I saw that paper, it needs more independent verification,” He said, before adding that “I am against using genome editing for enhancement.”

The problem, as Silva sees it, is that He may be blazing the trail for exactly that outcome, whether He intends to or not. Silva says that after his 2016 research was published, he received an uncomfortable amount of attention from some unnamed, elite Silicon Valley leaders who seem to be expressing serious interest in using CRISPR to give their children’s brains a boost through gene editing. [emphasis mine]

As such, Silva can be forgiven for not quite believing He’s claims that he wasn’t intending to alter the human genome for enhancement. …

The idea of designer babies isn’t new. As far back as Plato, the thought of using science to “engineer” a better human has been tossed about, but other than selective breeding, there really hasn’t been a path forward.

In the late 1800s, early 1900s, Eugenics made a real push to accomplish something along these lines, and the results were horrifying, even before Nazism. After eugenics mid-wifed the Holocaust in World War II, the concept of designer children has largely been left as fodder for science fiction since few reputable scientists would openly declare their intention to dabble in something once championed and pioneered by the greatest monsters of the 20th century.

Memories have faded though, and CRISPR significantly changes this decades-old calculus. CRISPR makes it easier than ever to target specific traits in order to add or subtract them from an embryos genetic code. Embryonic research is also a diverse enough field that some scientist could see pioneering designer babies as a way to establish their star power in academia while getting their names in the history books, [emphasis mine] all while working in relative isolation. They only need to reveal their results after the fact and there is little the scientific community can do to stop them, unfortunately.

When He revealed his research and data two days after announcing the births of Lulu and Nana, the gene-scientists at the Hong Kong conference were not all that impressed with the quality of He’s work. He has not provided access for fellow researchers to either his data on Lulu, Nana, and their family’s genetic data so that others can verify that Lulu and Nana’s CCR5 genes were in fact eliminated.

This almost rudimentary verification and validation would normally accompany a major announcement such as this. Neither has He’s work undergone a peer-review process and it hasn’t been formally published in any scientific journal—possibly for good reason.

Researchers such as Eric Topol, a geneticist at the Scripps Research Institute, have been finding several troubling signs in what little data He has released. Topol says that the editing itself was not precise and show “all kinds of glitches.”

Gaetan Burgio, a geneticist at the Australian National University, is likewise unimpressed with the quality of He’s work. Speaking of the slides He showed at the conference to support his claim, Burgio calls it amateurish, “I can believe that he did it because it’s so bad.”

Worse of all, its entirely possible that He actually succeeded in editing Lulu and Nana’s genetic code in an ad hoc, unethical, and medically substandard way. Sadly, there is no shortage of families with means who would be willing to spend a lot of money to design their idea of a perfect child, so there is certainly demand for such a “service.”

It’s nice to know (sarcasm icon) that the ‘Silicon Valley elite’ are willing to volunteer their babies for scientific experimentation in a bid to enhance intelligence.

The ethics of not saying anything

Natalie Kofler, a molecular biologist, wrote a February 26, 2019 Nature opinion piece and call to action on the subject of why scientists who were ‘in the know’ remained silent about He’s work prior to his announcements,

Millions [?] were shocked to learn of the birth of gene-edited babies last year, but apparently several scientists were already in the know. Chinese researcher He Jiankui had spoken with them about his plans to genetically modify human embryos intended for pregnancy. His work was done before adequate animal studies and in direct violation of the international scientific consensus that CRISPR–Cas9 gene-editing technology is not ready or appropriate for making changes to humans that could be passed on through generations.

Scholars who have spoken publicly about their discussions with He described feeling unease. They have defended their silence by pointing to uncertainty over He’s intentions (or reassurance that he had been dissuaded), a sense of obligation to preserve confidentiality and, perhaps most consistently, the absence of a global oversight body. Others who have not come forward probably had similar rationales. But He’s experiments put human health at risk; anyone with enough knowledge and concern could have posted to blogs or reached out to their deans, the US National Institutes of Health or relevant scientific societies, such as the Association for Responsible Research and Innovation in Genome Editing (see page 440). Unfortunately, I think that few highly established scientists would have recognized an obligation to speak up.

I am convinced that this silence is a symptom of a broader scientific cultural crisis: a growing divide between the values upheld by the scientific community and the mission of science itself.

A fundamental goal of the scientific endeavour is to advance society through knowledge and innovation. As scientists, we strive to cure disease, improve environmental health and understand our place in the Universe. And yet the dominant values ingrained in scientists centre on the virtues of independence, ambition and objectivity. That is a grossly inadequate set of skills with which to support a mission of advancing society.

Editing the genes of embryos could change our species’ evolutionary trajectory. Perhaps one day, the technology will eliminate heritable diseases such as sickle-cell anaemia and cystic fibrosis. But it might also eliminate deafness or even brown eyes. In this quest to improve the human race, the strengths of our diversity could be lost, and the rights of already vulnerable populations could be jeopardized.

Decisions about how and whether this technology should be used will require an expanded set of scientific virtues: compassion to ensure its applications are designed to be just, humility to ensure its risks are heeded and altruism to ensure its benefits are equitably distributed.

Calls for improved global oversight and robust ethical frameworks are being heeded. Some researchers who apparently knew of He’s experiments are under review by their universities. Chinese investigators have said He skirted regulations and will be punished. But punishment is an imperfect motivator. We must foster researchers’ sense of societal values.

Fortunately, initiatives popping up throughout the scientific community are cultivating a scientific culture informed by a broader set of values and considerations. The Scientific Citizenship Initiative at Harvard University in Cambridge, Massachusetts, trains scientists to align their research with societal needs. The Summer Internship for Indigenous Peoples in Genomics offers genomics training that also focuses on integrating indigenous cultural perspectives into gene studies. The AI Now Institute at New York University has initiated a holistic approach to artificial-intelligence research that incorporates inclusion, bias and justice. And Editing Nature, a programme that I founded, provides platforms that integrate scientific knowledge with diverse cultural world views to foster the responsible development of environmental genetic technologies.

Initiatives such as these are proof [emphasis mine] that science is becoming more socially aware, equitable and just. …

I’m glad to see there’s work being done on introducing a broader set of values into the scientific endeavour. That said, these programmes seem to be voluntary, i.e., people self-select, and those most likely to participate in these programmes are the ones who might be inclined to integrate social values into their work in the first place.

This doesn’t address the issue of how to deal with unscrupulous governments pressuring scientists to create designer babies along with hypercompetitive and possibly unscrupulous individuals such as the members of the ‘Silicon Valley insiders mentioned in Loeffler’s article, teaming up with scientists who will stop at nothing to get their place in the history books.

Like Kofler, I’m encouraged to see these programmes but I’m a little less convinced that they will be enough. What form it might take I don’t know but I think something a little more punitive is also called for.

CCR5 and freedom from HIV

I’ve added this piece about the Berlin and London patients because, back in November 2018, I failed to realize how compelling the idea of eradicating susceptibility to AIDS/HIV might be. Reading about some real life remissions helped me to understand some of He’s stated motivations a bit better. Unfortunately, there’s a major drawback described here in a March 5, 2019 news item on CBC (Canadian Broadcasting Corporation) online news attributed to Reuters,

An HIV-positive man in Britain has become the second known adult worldwide to be cleared of the virus that causes AIDS after he received a bone marrow transplant from an HIV-resistant donor, his doctors said.

The therapy had an early success with a man known as “the Berlin patient,” Timothy Ray Brown, a U.S. man treated in Germany who is 12 years post-transplant and still free of HIV. Until now, Brown was the only person thought to have been cured of infection with HIV, the virus that causes AIDS.

Such transplants are dangerous and have failed in other patients. They’re also impractical to try to cure the millions already infected.

In the latest case, the man known as “the London patient” has no trace of HIV infection, almost three years after he received bone marrow stem cells from a donor with a rare genetic mutation that resists HIV infection — and more than 18 months after he came off antiretroviral drugs.

“There is no virus there that we can measure. We can’t detect anything,” said Ravindra Gupta, a professor and HIV biologist who co-led a team of doctors treating the man.

Gupta described his patient as “functionally cured” and “in remission,” but cautioned: “It’s too early to say he’s cured.”

Gupta, now at Cambridge University, treated the London patient when he was working at University College London. The man, who has asked to remain anonymous, had contracted HIV in 2003, Gupta said, and in 2012 was also diagnosed with a type of blood cancer called Hodgkin’s lymphoma.

In 2016, when he was very sick with cancer, doctors decided to seek a transplant match for him.

“This was really his last chance of survival,” Gupta told Reuters.

Doctors found a donor with a gene mutation known as CCR5 delta 32, which confers resistance to HIV. About one per cent of people descended from northern Europeans have inherited the mutation from both parents and are immune to most HIV. The donor had this double copy of the mutation.

That was “an improbable event,” Gupta said. “That’s why this has not been observed more frequently.”

Most experts say it is inconceivable such treatments could be a way of curing all patients. The procedure is expensive, complex and risky. To do this in others, exact match donors would have to be found in the tiny proportion of people who have the CCR5 mutation.

Specialists said it is also not yet clear whether the CCR5 resistance is the only key [emphasis mine] — or whether the graft-versus-host disease may have been just as important. Both the Berlin and London patients had this complication, which may have played a role in the loss of HIV-infected cells, Gupta said.

Not only is there some question as to what role the CCR5 gene plays, there’s also a question as to whether or not we know what role genes play.

A big question: are genes what we thought?

Ken Richardson’s January 3, 2019 article for Nautilus (I stumbled across it on May 14, 2019 so I’m late to the party) makes and supports a startling statement, It’s the End of the Gene As We Know It We are not nearly as determined by our genes as once thought (Note: A link has been removed),

We’ve all seen the stark headlines: “Being Rich and Successful Is in Your DNA” (Guardian, July 12); “A New Genetic Test Could Help Determine Children’s Success” (Newsweek, July 10); “Our Fortunetelling Genes” make us (Wall Street Journal, Nov. 16); and so on.

The problem is, many of these headlines are not discussing real genes at all, but a crude statistical model of them, involving dozens of unlikely assumptions. Now, slowly but surely, that whole conceptual model of the gene is being challenged.

We have reached peak gene, and passed it.

The preferred dogma started to appear in different versions in the 1920s. It was aptly summarized by renowned physicist Erwin Schrödinger in a famous lecture in Dublin in 1943. He told his audience that chromosomes “contain, in some kind of code-script, the entire pattern of the individual’s future development and of its functioning in the mature state.”

Around that image of the code a whole world order of rank and privilege soon became reinforced. These genes, we were told, come in different “strengths,” different permutations forming ranks that determine the worth of different “races” and of different classes in a class-structured society. A whole intelligence testing movement was built around that preconception, with the tests constructed accordingly.

The image fostered the eugenics and Nazi movements of the 1930s, with tragic consequences. Governments followed a famous 1938 United Kingdom education commission in decreeing that, “The facts of genetic inequality are something that we cannot escape,” and that, “different children … require types of education varying in certain important respects.”

Today, 1930s-style policy implications are being drawn once again. Proposals include gene-testing at birth for educational intervention, embryo selection for desired traits, identifying which classes or “races” are fitter than others, and so on. And clever marketizing now sees millions of people scampering to learn their genetic horoscopes in DNA self-testing kits.[emphasis mine]

So the hype now pouring out of the mass media is popularizing what has been lurking in the science all along: a gene-god as an entity with almost supernatural powers. Today it’s the gene that, in the words of the Anglican hymn, “makes us high and lowly and orders our estate.”

… at the same time, a counter-narrative is building, not from the media but from inside science itself.

So it has been dawning on us is that there is no prior plan or blueprint for development: Instructions are created on the hoof, far more intelligently than is possible from dumb DNA. That is why today’s molecular biologists are reporting “cognitive resources” in cells; “bio-information intelligence”; “cell intelligence”; “metabolic memory”; and “cell knowledge”—all terms appearing in recent literature.1,2 “Do cells think?” is the title of a 2007 paper in the journal Cellular and Molecular Life Sciences.3 On the other hand the assumed developmental “program” coded in a genotype has never been described.

It is such discoveries that are turning our ideas of genetic causation inside out. We have traditionally thought of cell contents as servants to the DNA instructions. But, as the British biologist Denis Noble insists in an interview with the writer Suzan Mazur,1 “The modern synthesis has got causality in biology wrong … DNA on its own does absolutely nothing [ emphasis mine] until activated by the rest of the system … DNA is not a cause in an active sense. I think it is better described as a passive data base which is used by the organism to enable it to make the proteins that it requires.”

I highly recommend reading Richardson’s article in its entirety. As well, you may want to read his book, ” Genes, Brains and Human Potential: The Science and Ideology of Intelligence .”

As for “DNA on its own doing absolutely nothing,” that might be a bit of a eye-opener for the Silicon Valley elite types investigating cognitive advantages attributed to the lack of a CCR5 gene. Meanwhile, there are scientists inserting a human gene associated with brain development into monkeys,

Transgenic monkeys and human intelligence

An April 2, 2019 news item on describes research into transgenic monkeys,

Researchers from China and the United States have created transgenic monkeys carrying a human gene that is important for brain development, and the monkeys showed human-like brain development.

Scientists have identified several genes that are linked to primate brain size. MCPH1 is a gene that is expressed during fetal brain development. Mutations in MCPH1 can lead to microcephaly, a developmental disorder characterized by a small brain.

In the study published in the Beijing-based National Science Review, researchers from the Kunming Institute of Zoology, Chinese Academy of Sciences, the University of North Carolina in the United States and other research institutions reported that they successfully created 11 transgenic rhesus monkeys (eight first-generation and three second-generation) carrying human copies of MCPH1.

According to the research article, brain imaging and tissue section analysis showed an altered pattern of neuron differentiation and a delayed maturation of the neural system, which is similar to the developmental delay (neoteny) in humans.

Neoteny in humans is the retention of juvenile features into adulthood. One key difference between humans and nonhuman primates is that humans require a much longer time to shape their neuro-networks during development, greatly elongating childhood, which is the so-called “neoteny.”

Here’s a link to and a citation for the paper,

Transgenic rhesus monkeys carrying the human MCPH1 gene copies show human-like neoteny of brain development by Lei Shi, Xin Luo, Jin Jiang, Yongchang Chen, Cirong Liu, Ting Hu, Min Li, Qiang Lin, Yanjiao Li, Jun Huang Hong Wang, Yuyu Niu, Yundi Shi, Martin Styner, Jianhong Wang, Yi Lu, Xuejin Sun, Hualin Yu, Weizhi Ji, Bing Su. National Science Review, nwz043, Published: 27 March 2019

This appears to be an open access paper,

Transgenic monkeys and an ethical uproar

Predictably, this research set off alarms as Sharon Kirkey’s April 12, 2019 article for the National Post describes in detail (Note: A link has been removed)l,

Their brains may not be bigger than normal, but monkeys created with human brain genes are exhibiting cognitive changes that suggest they might be smarter — and the experiments have ethicists shuddering.

In the wake of the genetically modified human babies scandal, Chinese scientists [as a scientist from the US] are drawing fresh condemnation from philosophers and ethicists, this time over the announcement they’ve created transgenic monkeys with elements of a human brain.

Six of the monkeys died, however the five survivors “exhibited better short-term memory and shorter reaction time” compared to their wild-type controls, the researchers report in the journa.

According to the researchers, the experiments represent the first attempt to study the genetic basis of human brain origin using transgenic monkeys. The findings, they insist, “have the potential to provide important — and potentially unique — insights into basic questions of what actually makes humans unique.”

For others, the work provokes a profoundly moral and visceral uneasiness. Even one of the collaborators — University of North Carolina computer scientist Martin Styner — told MIT Technology Review he considered removing his name from the paper, which he said was unable to find a publisher in the West.

“Now we have created this animal which is different than it is supposed to be,” Styner said. “When we do experiments, we have to have a good understanding of what we are trying to learn, to help society, and that is not the case here.” l

In an email to the National Post, Styner said he has an expertise in medical image analysis and was approached by the researchers back in 2011. He said he had no input on the science in the project, beyond how to best do the analysis of their MRI data. “At the time, I did not think deeply enough about the ethical consideration.”


When it comes to the scientific use of nonhuman primates, ethicists say the moral compass is skewed in cases like this.

Given the kind of beings monkeys are, “I certainly would have thought you would have had to have a reasonable expectation of high benefit to human beings to justify the harms that you are going to have for intensely social, cognitively complex, emotional animals like monkeys,” said Letitia Meynell, an associate professor in the department of philosophy at Dalhousie University in Halifax.

“It’s not clear that this kind of research has any reasonable expectation of having any useful application for human beings,” she said.

The science itself is also highly dubious and fundamentally flawed in its logic, she said.
“If you took Einstein as a baby and you raised him in the lab he wouldn’t turn out to be Einstein,” Meynell said. “If you’re actually interested in studying the cognitive complexity of these animals, you’re not going to get a good representation of that by raising them in labs, because they can’t develop the kind of cognitive and social skills they would in their normal environment.”

The Chinese said the MCPH1 gene is one of the strongest candidates for human brain evolution. But looking at a single gene is just bad genetics, Meynell said. Multiple genes and their interactions affect the vast majority of traits.

My point is that there’s a lot of research focused on intelligence and genes when we don’t really know what role genes actually play and when there doesn’t seem to be any serious oversight.

Global plea for moratorium on heritable genome editing

A March 13, 2019 University of Otago (New Zealand) press release (also on EurekAlert) describes a global plea for a moratorium,

A University of Otago bioethicist has added his voice to a global plea for a moratorium on heritable genome editing from a group of international scientists and ethicists in the wake of the recent Chinese experiment aiming to produce HIV immune children.

In an article in the latest issue of international scientific journal Nature, Professor Jing-Bao Nie together with another 16 [17] academics from seven countries, call for a global moratorium on all clinical uses of human germline editing to make genetically modified children.

They would like an international governance framework – in which nations voluntarily commit to not approve any use of clinical germline editing unless certain conditions are met – to be created potentially for a five-year period.

Professor Nie says the scientific scandal of the experiment that led to the world’s first genetically modified babies raises many intriguing ethical, social and transcultural/transglobal issues. His main personal concerns include what he describes as the “inadequacy” of the Chinese and international responses to the experiment.

“The Chinese authorities have conducted a preliminary investigation into the scientist’s genetic misadventure and issued a draft new regulation on the related biotechnologies. These are welcome moves. Yet, by putting blame completely on the rogue scientist individually, the institutional failings are overlooked,” Professor Nie explains.

“In the international discourse, partly due to the mentality of dichotomising China and the West, a tendency exists to characterise the scandal as just a Chinese problem. As a result, the global context of the experiment and Chinese science schemes have been far from sufficiently examined.”

The group of 17 [18] scientists and bioethicists say it is imperative that extensive public discussions about the technical, scientific, medical, societal, ethical and moral issues must be considered before germline editing is permitted. A moratorium would provide time to establish broad societal consensus and an international framework.

“For germline editing to even be considered for a clinical application, its safety and efficacy must be sufficient – taking into account the unmet medical need, the risks and potential benefits and the existence of alternative approaches,” the opinion article states.

Although techniques have improved in recent years, germline editing is not yet safe or effective enough to justify any use in the clinic with the risk of failing to make the desired change or of introducing unintended mutations still unacceptably high, the scientists and ethicists say.

“No clinical application of germline editing should be considered unless its long-term biological consequences are sufficiently understood – both for individuals and for the human species.”

The proposed moratorium does not however, apply to germline editing for research uses or in human somatic (non-reproductive) cells to treat diseases.

Professor Nie considers it significant that current presidents of the UK Royal Society, the US National Academy of Medicine and the Director and Associate Director of the US National Institute of Health have expressed their strong support for such a proposed global moratorium in two correspondences published in the same issue of Nature. The editorial in the issue also argues that the right decision can be reached “only through engaging more communities in the debate”.

“The most challenging questions are whether international organisations and different countries will adopt a moratorium and if yes, whether it will be effective at all,” Professor Nie says.

A March 14, 2019 news item on provides a précis of the Comment in Nature. Or, you ,can access the Comment with this link

Adopt a moratorium on heritable genome editing; Eric Lander, Françoise Baylis, Feng Zhang, Emmanuelle Charpentier, Paul Berg and specialists from seven countries call for an international governance framework.signed by: Eric S. Lander, Françoise Baylis, Feng Zhang, Emmanuelle Charpentier, Paul Berg, Catherine Bourgain, Bärbel Friedrich, J. Keith Joung, Jinsong Li, David Liu, Luigi Naldini, Jing-Bao Nie, Renzong Qiu, Bettina Schoene-Seifert, Feng Shao, Sharon Terry, Wensheng Wei, & Ernst-Ludwig Winnacker. Nature 567, 165-168 (2019) doi: 10.1038/d41586-019-00726-5

This Comment in Nature is open access.

World Health Organization (WHO) chimes in

Better late than never, eh? The World Health Organization has called heritable gene editing of humans ‘irresponsible’ and made recommendations. From a March 19, 2019 news item on the Canadian Broadcasting Corporation’s Online news webpage,

A panel convened by the World Health Organization said it would be “irresponsible” for scientists to use gene editing for reproductive purposes, but stopped short of calling for a ban.

The experts also called for the U.N. health agency to create a database of scientists working on gene editing. The recommendation was announced Tuesday after a two-day meeting in Geneva to examine the scientific, ethical, social and legal challenges of such research.

“At this time, it is irresponsible for anyone to proceed” with making gene-edited babies since DNA changes could be passed down to future generations, the experts said in a statement.

Germline editing has been on my radar since 2015 (see my May 14, 2015 posting) and the probability that someone would experiment with viable embryos and bring them to term shouldn’t be that much of a surprise.

Slow science from Canada

Canada has banned germline editing but there is pressure to lift that ban. (I touched on the specifics of the campaign in an April 26, 2019 posting.) This March 17, 2019 essay on The Conversation by Landon J Getz and Graham Dellaire, both of Dalhousie University (Nova Scotia, Canada) elucidates some of the discussion about whether research into germline editing should be slowed down.

Naughty (or Haughty, if you prefer) scientists

There was scoffing from some, if not all, members of the scientific community about the potential for ‘designer babies’ that can be seen in an excerpt from an article by Ed Yong for The Atlantic (originally published in my ,August 15, 2017 posting titled: CRISPR and editing the germline in the US (part 2 of 3): ‘designer babies’?),

Ed Yong in an Aug. 2, 2017 article for The Atlantic offered a comprehensive overview of the research and its implications (unusually for Yong, there seems to be mildly condescending note but it’s worth ignoring for the wealth of information in the article; Note: Links have been removed),

” … the full details of the experiment, which are released today, show that the study is scientifically important but much less of a social inflection point than has been suggested. “This has been widely reported as the dawn of the era of the designer baby, making it probably the fifth or sixth time people have reported that dawn,” says Alta Charo, an expert on law and bioethics at the University of Wisconsin-Madison. “And it’s not.”

Then about 15 months later, the possibility seemed to be realized.

Interesting that scientists scoffed at the public’s concerns (you can find similar arguments about robots and artificial intelligence not being a potentially catastrophic problem), yes? Often, nonscientists’ concerns are dismissed as being founded in science fiction.

To be fair, there are times when concerns are overblown, the difficulty is that it seems the scientific community’s default position is to uniformly dismiss concerns rather than approaching them in a nuanced fashion. If the scoffers had taken the time to think about it, germline editing on viable embryos seems like an obvious and inevitable next step (as I’ve noted previously).

At this point, no one seems to know if He actually succeeded at removing CCR5 from Lulu’s and Nana’s genomes. In November 2018, scientists were guessing that at least one of the twins was a ‘mosaic’. In other words, some of her cells did not include CCR5 while others did.

Parents, children, competition

A recent college admissions scandal in the US has highlighted the intense competition to get into high profile educational institutions. (This scandal brought to mind the Silicon Valey elite who wanted to know more about gene editing that might result in improved cognitive skills.)

Since it can be easy to point the finger at people in other countries, I’d like to note that there was a Canadian parent among these wealthy US parents attempting to give their children advantages by any means, legal or not. (Note: These are alleged illegalities.) From a March 12, 2019 news article by Scott Brown, Kevin Griffin, and Keith Fraser for the Vancouver Sun,

Vancouver businessman and former CFL [Canadian Football League] player David Sidoo has been charged with conspiracy to commit mail and wire fraud in connection with a far-reaching FBI investigation into a criminal conspiracy that sought to help privileged kids with middling grades gain admission to elite U.S. universities.

In a 12-page indictment filed March 5 [2019] in the U.S. District Court of Massachusetts, Sidoo is accused of making two separate US$100,000 payments to have others take college entrance exams in place of his two sons.

Sidoo is also accused of providing documents for the purpose of creating falsified identification cards for the people taking the tests.

In what is being called the biggest college-admissions scam ever prosecuted by the U.S. Justice Department, Sidoo has been charged with nearly 50 other people. Nine athletic coaches and 33 parents including Hollywood actresses Felicity Huffman and Lori Loughlin. are among those charged in the investigation, dubbed Operation Varsity Blues.

According to the indictment, an unidentified person flew from Tampa, Fla., to Vancouver in 2011 to take the Scholastic Aptitude Test (SAT) in place of Sidoo’s older son and was directed not to obtain too high a score since the older son had previously taken the exam, obtaining a score of 1460 out of a possible 2400.

A copy of the resulting SAT score — 1670 out of 2400 — was mailed to Chapman University, a private university in Orange, Calif., on behalf of the older son, who was admitted to and ultimately enrolled in the university in January 2012, according to the indictment.

It’s also alleged that Sidoo arranged to have someone secretly take the older boy’s Canadian high school graduation exam, with the person posing as the boy taking the exam in June 2012.

The Vancouver businessman is also alleged to have paid another $100,000 to have someone take the SAT in place of his younger son.

Sidoo, an investment banker currently serving as CEO of Advantage Lithium, was awarded the Order of B.C. in 2016 for his philanthropic efforts.

He is a former star with the UBC [University of British Columbia] Thunderbirds football team and helped the school win its first Vanier Cup in 1982. He went on to play five seasons in the CFL with the Saskatchewan Roughriders and B.C. Lions.

Sidoo is a prominent donor to UBC and is credited with spearheading an alumni fundraising campaign, 13th Man Foundation, that resuscitated the school’s once struggling football team. He reportedly donated $2 million of his own money to support the program.

Sidoo Field at UBC’s Thunderbird Stadium is named in his honour.

In 2016, he received the B.C. [British Columbia] Sports Hall of Fame’s W.A.C. Bennett Award for his contributions to the sporting life of the province.

The question of whether or not these people like the ‘Silicon Valley elite’ (mentioned in John Loeffler’s February 22, 2019 article) would choose to tinker with their children’s genome if it gave them an advantage, is still hypothetical but it’s easy to believe that at least some might seriously consider the possibility especially if the researcher or doctor didn’t fully explain just how little is known about the impact of tinkering with the genome. For example, there’s a big question about whether those parents in China fully understood what they signed up for.

By the way, cheating scandals aren’t new (see Vanity Fair’s Schools For Scandal; The Inside Dramas at 16 of America’s Most Elite Campuses—Plus Oxford! Edited by Graydon Carter, published in August 2018 and covering 25 years of the magazine’s reporting). On a similar line, there’s this March13, 2019 essay which picks apart some of the hierarchical and power issues at play in the US higher educational system which led to this latest (but likely not last) scandal.

Scientists under pressure

While Kofler’s February 26, 2019 Nature opinion piece and call to action seems to address the concerns regarding germline editing by advocating that scientists become more conscious of how their choices impact society, as I noted earlier, the ideas expressed seem a little ungrounded in harsh realities. Perhaps it’s time to give some recognition to the various pressures put on scientists from their own governments and from an academic environment that fosters ‘success’ at any cost to peer pressure, etc. (For more about the costs of a science culture focused on success, read this March 2, 2019 blog posting by Jon Tennant on for a breakdown.)

One other thing I should mention, for some scientists getting into the history books, winning Nobel prizes, etc. is a very important goal. Scientists are people too.

Some thoughts

There seems to be a great disjunction between what Richardson presents as an alternative narrative to the ‘gene-god’ and how genetic research is being performed and reported on. What is clear to me is that no one really understands genetics and this business of inserting and deleting genes is essentially research designed to satisfy curiosity and/or allay fears about being left behind in a great scientific race to a an unknown destination.

I’d like to see some better reporting and a more agile response by the scientific community, the various governments, and international agencies. What shape or form a more agile response might take, I don’t know but I’d like to see some efforts.

Back to the regular programme

There’s a lot about CRISPR here on this blog. A simple search of ‘CRISPR ‘in the blog’s search engine should get you more than enough information about the technology and the various issues ranging from intellectual property to risks and more.

The three part series (CRISPR and editing the germline in the US …), mentioned previously, was occasioned by the publication of a study on germline editing research with nonviable embryos in the US. The 2017 research was done at the Oregon Health and Science University by Shoukhrat Mitalipov following similar research published by Chinese scientists in 2015. The series gives relatively complete coverage of the issues along with an introduction to CRISPR and embedded video describing the technique. Here’s part 1 to get you started..

Walking again with exoskeletons and brain-controlled, non-invasive muscle stimulation enabling people to walk

I have two news bits about paraplegics and the possibility of walking. The first is from Alberta, Canada and the second is from Brazil.


The fellow in the video is wearing a robotic exoskeleton. As you can see, it’s not perfect but it represents an extraordinary breakthrough (from an April 16, 2019 article by Sarah Lawrynuik for the Canadian Broadcasting Corporation [CBC] Radio),

On his fifteenth birthday in December 2015, Calgary’s Alex McEwan was injured in a tobogganing accident with friends and lost the ability to walk. It’s the kind of change that could destroy a person, but Alex has thrived and is learning new skills. Watch him walk onstage, with some help from a powered exoskeleton, to receive his diploma. 1:21

Sometimes events conspire to move us in a completely unexpected ways. After his accident, Alex McEwan participated in a very special study (from an August 3, 2019 article by Colin Zak for Alberta Health Services),

Researchers at Foothills Medical Centre (FMC) are the first in Canada to examine the benefits of using an exoskeleton robotic device to rehabilitate patients with spinal cord injuries (SCI) in the days and weeks following their injury.

The device, known as the Ekso Bionic Exoskeleton, consists of a metal frame that supports and stabilizes a patient’s torso, core, legs and feet. It is moved robotically by a therapist, enabling patients with a spinal cord injury to get up and walk around. Although it is controlled by remote control, the device offers varying levels of physical control by the patient, depending on the nature and extent of their injury.

Dr. Ho [ Dr. Chester Ho, Head of Physical Medicine and Rehabilitation at FMC ] says exoskeletons may potentially promote recovery and reduce complications in SCI patients by reducing loss of bone and muscle mass caused by spending so much time lying down, and also improve breathing and bowel function.

The year-long study, which begins this summer, will include between five and 10 patients selected from across Calgary [Alberta]. It aims to examine whether treatment is safe and feasible in the days and weeks after an SCI. This study will be followed by larger studies involving more patients.

Participants in the study will receive 60-minute therapy sessions with the exoskeleton device two to three times a week, for a total of 25 training hours over an eight- to 10-week period. Safety and feasibility outcomes will be monitored and tracked by the research team throughout all sessions.

Before the advent of exoskeletons, rehabilitation for patients with an SCI required them to be hoisted with a physical therapist moving their legs.

“Every step is different with this device, so patients learn from their mistakes in real time. Patients really like to use the device; it gives them hope.”

Alex, [emphasis mine] 15, sustained a spinal cord injury while tobogganing last December.

He says rehabilitation sessions with the exoskeleton have made a difference in how he feels and gives him hope for the future.

Over 2 1/2 years later, the CBC has made a radio documentary about this study and the people who took part. Lawrynuik’s April 16, 2019 article describes some highlights from the radio documentary,

Imagine waking up in a hospital bed surrounded by the beeps and whirring sounds of the machines keeping you alive. The doctor tells you that you will likely never walk again.

But then, just as you begin to process that news, a physiotherapist shows up at your bedside and says, “Hold up. I might have a special opportunity for you.”

That’s the journey taken by a number of Albertans who landed in Calgary’s Foothills Medical Centre after accidents or trauma to their spine in the last three years. Three of those people are Alex McEwan, a university student in Lethbridge; Jean Ogilvie, a 77-year-old woman living in Calgary; and Josh Pelland, a former climber turned motivational speaker in Three Hills, Alta.

All three are united by a technology called an exoskeleton, created by a company called Ekso Bionics, that allowed them to walk despite no longer being able to use their legs. 

“The first time was a bit scary actually,” Ogilvie said. “It’s like a great big skeleton that sort of clasps you in its body. [It’s] black and all sorts of straps and sensors tell you how I’m doing.”

Pelland agrees about how daunting the experience is to start.

“They just said, ‘OK, the machine is going to assist you and lift you up.’ And I was a bit like, ‘OK, this is the strangest thing ever.'”

Once the frame of the exoskeleton is strapped along the outside of the patient’s legs and up their back, starting from the seated position, it does lift them completely without the help of their own muscles.

From there they shift their upper-body weight within the machine to hit certain targets — once your body weight is shifted forward and laterally enough, a beep sounds and the exoskeleton pulls each leg forward, one at a time. 

As patients learn to use the machine, they walk with the assistance of a walker. Then, as they progress, they upgrade to forearm crutches. The entire time, they’re accompanied by the man behind the machine, Kyle McIntosh.

McIntosh is a physiotherapist and he worked with the exoskeleton both to help patients and to conduct research into the machine’s impact on rehabilitation.

After being discharged and living once again without the exoskeleton, and therefore without the ability to walk — McEwan got an idea: maybe he’d be allowed to use the robot, just one last time.

“High school wasn’t high school for me. I only really got one semester of grade 10 before I broke my spine. So that first semester was great. I enjoyed it. I played sports. I was a good student. But then it was no longer about high school anymore. It was more about adjusting to my new life.”

McIntosh and McEwan hatched the plan together and kept it a closely guarded secret. Then, on the day McEwan was set to graduate from Grade 12, he asked to be placed last on the list of students to cross the stage.

“I remember taking a first few steps and not hearing very much. Hearing people cheer because I was the kid in the wheelchair at the high school, so it makes sense. But the second they saw the canes and my first few steps, just one kid erupted: ‘Yeah!’ And then everyone went crazy.”

“I think walking across the stage — just like I got to walk into my high school on the first day of Grade 10 — was a really good closing story. The chapter of me learning to live in a wheelchair was done. And it was now my turn to go live my life. So that’s why I think it was such an important day because it gave me a lot of closure. I got to walk into the high school, I got to walk out.”

If you have the time, you might want to read Lawrynuik’s April 16, 2019 article in its entirety. It turns out that the study did much more than give a people a chance to walk again, even if just for a short time.

Anyone interested in the robotic, wearable exoskeleton used in the study can go here to EksoHealth, the company that produces the EksoGT, a bionic exoskeleton. (Lawrynuik’s article has another name for the product, i.e., Ekso Bionic Exoskeleton but all I could find was the EksoGT.)

Brazil and Walk Again

The most recent post featuring the Walk Again project is my May 20, 2014 edition which was part of a larger series on ‘Brain research, ethics, and nanotechnology’. The May 20, 2014 posting covered Walk Again’s debut at the 2014 World Cup (soccer/football) in Brazil. Unfortunately,, the lead researcher Miguel Nicolelis oversold the technology. I think people were expecting someone with paraplegia to come bounding out onto the field and give a flashy opening kick for the tournament what they saw was something a great deal more restrained.

The person was wheeled out onto the field, stood up, shuffled a bit, and nudged the ball with his foot. It represented a huge breakthrough but it wasn’t flashy.

The latest from Walk Again is in a May 14, 2019 Associação Alberto Santos Dumont para Apoio à Pesquisa press release on EurekAlert,

In another major clinical breakthrough of the Walk Again Project, a non-profit international consortium aimed at developing new neuro-rehabilitation protocols, technologies and therapies for spinal cord injury, two patients with paraplegia regained the ability to walk with minimal assistance, through the employment of a fully non-invasive brain-machine interface that does not require the use of any invasive spinal cord surgical procedure. The results of this study appeared on the May 1 [2019] issue of the journal Scientific Reports.

The two patients with paraplegia (AIS C) used their own brain activity to control the non-invasive delivery of electrical pulses to a total of 16 muscles (eight in each leg), allowing them to produce a more physiological walk than previously reported, requiring only a conventional walker and a body weight support system as assistive devices. Overall, the two patients were able to produce more than 4,500 steps using this new technology, which combines a non-invasive brain-machine interface, based on a 16-channel EEG, to control a multi-channel functional electrical stimulation system (FES), tailored to produce a much smoother gait pattern than the state of the art of this technique.

“What surprised us was that, in addition to allowing these patients to walk with little help, one of them displayed a clear motor improvement by practicing with this new approach. Patients required approximatively [sic] 25 sessions to master the training before they were able to walk using this apparatus,” said Solaiman Shokur one of the authors of the study.

The two patients that used this new rehabilitation approach had previously participated in the long-term neurorehabilitation study carried out using the Walk Again Project Neurorehabilitation (WANR) protocol. As reported in a recent publication from the same team (Shokur et al., PLoS One, Nov. 2018), all seven patients who participated in that protocol for a period of 28 months improved their clinical status, from complete paraplegia (AIS A or B, meaning no motor functions below the level of the injury, according to the ASIA classification) to partial paraplegia (AIS C, meaning partial recovery of sensory and motor function below the injury level). This significant neurological recovery included major clinical improvements in sensory discrimination (tactile, nociception, vibration, and pressure), voluntary motor control of abdomen and leg muscles, and important gains in autonomic control, such as bladder, bowel, and sexual functions.

“The last two studies published by the Walk Again Project clearly indicate that partial neurological and functional recovery can be induced in chronic spinal cord injury patients by combining multiple non-invasive technologies that are based around the concept of using a brain-machine interface to control different types of actuators, like virtual avatars, robotic walkers, or muscle stimulating devices, to allow the total involvement of patients in their own rehabilitation routine,” said Miguel Nicolelis, scientific director of the Walk Again Project and one of the authors of the study.

In a recent report by another group, one AIS C and two AIS D patients were able to walk thanks to the employment of an invasive method for spinal cord electrical stimulation, which required a spinal surgical procedure. In contrast, in the present study two AIS C patients – which originally were AIS A (see Supplemental Material below)- and a third AIS B subject, who recently achieved similar results, were able to regain a significant degree of autonomous walking without the need for such invasive treatments. Instead, these patients only received electrical stimulation patterns delivered to the skin surface of their legs, so that a total of eight muscles in each limb could be electrically stimulated in a physiologically accurate sequence. This was done in order to produce a smoother and more natural pattern of locomotion.

“Crucial for this implementation was the development of a closed-loop controller that allowed real-time correction of the patients’ walking pattern, taking into account muscle fatigue and external perturbations, in order to produce a predefined gait trajectory. Another major component of our approach was the use of a wearable haptic display to deliver tactile feedback to the patients´ forearms in order to provide them with a continuous source of proprioceptive feedback related to their walking,” said Solaiman Shokur.

To control the pattern of electrical muscle stimulation in each leg, these patients utilized an EEG-based brain-machine interface. In this setup, patients learned to alternate the generation of “stepping motor imagery” activity in their right and left motor cortices, in order to create alternated movements of their left and right legs.

According to the authors, the patients exhibited not only “less dependency on walking assistance, but also partial neurological recovery, with substantial rates of motor improvement in one of them.” The improvement in motor control in this last AIS C patient was 9 points in the lower extremity motor score (LEMS), which was comparable with that observed using invasive spinal cord stimulation.

Based on the results obtained over the past 5 years, the WAP now intends to combine all its neurorehabilitation tools into a single integrated, non-invasive platform to treat spinal cord injury patients. This platform will allow patients to begin training soon after the injury occurs. It will also allow the employment of a multi-dimensional integrated brain-machine interface capable of simultaneously controlling virtual and robotic actuators (like a lowerlimb exoskeleton), a multi-channel non-invasive electrical muscle stimulation system (like the FES used in the present study), and a novel non-invasive spinal cord stimulation approach. In this final configuration, this WAP platform will incorporate all these technologies together in order to maximize neurological and functional recovery in the shortest possible time, without the need of any invasive procedure.

According to Dr. Nicolelis, “there is no silver bullet to treat spinal cord injuries. More and more, it looks like we need to implement multiple techniques simultaneously to achieve the best neurorehabilitation results. In this context, it is also imperative to consider the occurrence of cortical plasticity as a major component in the planning of our rehabilitation approach.”

Here’s a link to and a citation for the paper,

Non-invasive, Brain-controlled Functional Electrical Stimulation for Locomotion Rehabilitation in Individuals with Paraplegia by Aurelie Selfslagh, Solaiman Shokur, Debora S. F. Campos, Ana R. C. Donati, Sabrina Almeida, Seidi Y. Yamauti, Daniel B. Coelho, Mohamed Bouri & Miguel A. L. Nicolelis. Scientific Reports volume 9, Article number: 6782 (2019) DOI: Published 01 May 2019

This paper is open access.

There’s also a video for Walk Again,

A solar, self-charging supercapacitor for wearable technology

Ravinder Dahiya, Carlos García Núñez, and their colleagues at the University of Glasgow (Scotland) strike again (see my May 10, 2017 posting for their first ‘solar-powered graphene skin’ research announcement). Last time it was all about robots and prosthetics, this time they’ve focused on wearable technology according to a July 18, 2018 news item on,

A new form of solar-powered supercapacitor could help make future wearable technologies lighter and more energy-efficient, scientists say.

In a paper published in the journal Nano Energy, researchers from the University of Glasgow’s Bendable Electronics and Sensing Technologies (BEST) group describe how they have developed a promising new type of graphene supercapacitor, which could be used in the next generation of wearable health sensors.

A July 18, 2018 University of Glasgow press release, which originated the news item, explains further,

Currently, wearable systems generally rely on relatively heavy, inflexible batteries, which can be uncomfortable for long-term users. The BEST team, led by Professor Ravinder Dahiya, have built on their previous success in developing flexible sensors by developing a supercapacitor which could power health sensors capable of conforming to wearer’s bodies, offering more comfort and a more consistent contact with skin to better collect health data.

Their new supercapacitor uses layers of flexible, three-dimensional porous foam formed from graphene and silver to produce a device capable of storing and releasing around three times more power than any similar flexible supercapacitor. The team demonstrated the durability of the supercapacitor, showing that it provided power consistently across 25,000 charging and discharging cycles.

They have also found a way to charge the system by integrating it with flexible solar powered skin already developed by the BEST group, effectively creating an entirely self-charging system, as well as a pH sensor which uses wearer’s sweat to monitor their health.

Professor Dahiya said: “We’re very pleased by the progress this new form of solar-powered supercapacitor represents. A flexible, wearable health monitoring system which only requires exposure to sunlight to charge has a lot of obvious commercial appeal, but the underlying technology has a great deal of additional potential.

“This research could take the wearable systems for health monitoring to remote parts of the world where solar power is often the most reliable source of energy, and it could also increase the efficiency of hybrid electric vehicles. We’re already looking at further integrating the technology into flexible synthetic skin which we’re developing for use in advanced prosthetics.” [emphasis mine]

In addition to the team’s work on robots, prosthetics, and graphene ‘skin’ mentioned in the May 10, 2017 posting the team is working on a synthetic ‘brainy’ skin for which they have just received £1.5m funding from the Engineering and Physical Science Research Council (EPSRC).

Brainy skin

A July 3, 2018 University of Glasgow press release discusses the proposed work in more detail,

A robotic hand covered in ‘brainy skin’ that mimics the human sense of touch is being developed by scientists.

University of Glasgow’s Professor Ravinder Dahiya has plans to develop ultra-flexible, synthetic Brainy Skin that ‘thinks for itself’.

The super-flexible, hypersensitive skin may one day be used to make more responsive prosthetics for amputees, or to build robots with a sense of touch.

Brainy Skin reacts like human skin, which has its own neurons that respond immediately to touch rather than having to relay the whole message to the brain.

This electronic ‘thinking skin’ is made from silicon based printed neural transistors and graphene – an ultra-thin form of carbon that is only an atom thick, but stronger than steel.

The new version is more powerful, less cumbersome and would work better than earlier prototypes, also developed by Professor Dahiya and his Bendable Electronics and Sensing Technologies (BEST) team at the University’s School of Engineering.

His futuristic research, called neuPRINTSKIN (Neuromorphic Printed Tactile Skin), has just received another £1.5m funding from the Engineering and Physical Science Research Council (EPSRC).

Professor Dahiya said: “Human skin is an incredibly complex system capable of detecting pressure, temperature and texture through an array of neural sensors that carry signals from the skin to the brain.

“Inspired by real skin, this project will harness the technological advances in electronic engineering to mimic some features of human skin, such as softness, bendability and now, also sense of touch. This skin will not just mimic the morphology of the skin but also its functionality.

“Brainy Skin is critical for the autonomy of robots and for a safe human-robot interaction to meet emerging societal needs such as helping the elderly.”

Synthetic ‘Brainy Skin’ with sense of touch gets £1.5m funding. Photo of Professor Ravinder Dahiya

This latest advance means tactile data is gathered over large areas by the synthetic skin’s computing system rather than sent to the brain for interpretation.

With additional EPSRC funding, which extends Professor Dahiya’s fellowship by another three years, he plans to introduce tactile skin with neuron-like processing. This breakthrough in the tactile sensing research will lead to the first neuromorphic tactile skin, or ‘brainy skin.’

To achieve this, Professor Dahiya will add a new neural layer to the e-skin that he has already developed using printing silicon nanowires.

Professor Dahiya added: “By adding a neural layer underneath the current tactile skin, neuPRINTSKIN will add significant new perspective to the e-skin research, and trigger transformations in several areas such as robotics, prosthetics, artificial intelligence, wearable systems, next-generation computing, and flexible and printed electronics.”

The Engineering and Physical Sciences Research Council (EPSRC) is part of UK Research and Innovation, a non-departmental public body funded by a grant-in-aid from the UK government.

EPSRC is the main funding body for engineering and physical sciences research in the UK. By investing in research and postgraduate training, the EPSRC is building the knowledge and skills base needed to address the scientific and technological challenges facing the nation.

Its portfolio covers a vast range of fields from healthcare technologies to structural engineering, manufacturing to mathematics, advanced materials to chemistry. The research funded by EPSRC has impact across all sectors. It provides a platform for future UK prosperity by contributing to a healthy, connected, resilient, productive nation.

It’s fascinating to note how these pieces of research fit together for wearable technology and health monitoring and creating more responsive robot ‘skin’ and, possibly, prosthetic devices that would allow someone to feel again.

The latest research paper

Getting back the solar-charging supercapacitors mentioned in the opening, here’s a link to and a citation for the team’s latest research paper,

Flexible self-charging supercapacitor based on graphene-Ag-3D graphene foam electrodes by Libu Manjakka, Carlos García Núñez, Wenting Dang, Ravinder Dahiya. Nano Energy Volume 51, September 2018, Pages 604-612 DOI:

This paper is open access.

Call for abstracts: Seventh annual conference on governance of emerging technologies & science (GETS)

The conference itself will be held from May 22 – 24, 2019 at Arizona State University (ASU) and the deadline for abstracts is January 31, 2019. Here’s the news straight from the January 8, 2019 email announcement,

The Seventh Annual Conference on Governance of Emerging Technologies & Science (GETS)

May 22-24, 2019 / ASU / Sandra Day O’Connor College of Law
111 E. Taylor St., Phoenix, AZ
The conference will consist of plenary and session presentations and discussions on regulatory, governance, legal, policy, social and ethical aspects of emerging technologies, including nanotechnology, synthetic biology, gene editing, biotechnology, genomics, personalized medicine, digital health, human enhancement, artificial intelligence, virtual reality, internet of things (IoT), blockchain and much, much more!
Submit Your Abstract Here: 2019 Abstract
Conference Website
Call for abstracts:
The co-sponsors invite submission of abstracts for proposed presentations. Submitters of abstracts need not provide a written paper, although provision will be made for posting and possible post-conference publication of papers for those who are interested. 
Abstracts are invited for any aspect or topic relating to the governance of emerging technologies, including any of the technologies listed above.
·         Abstracts should not exceed 500 words and must contain your name and email address.
·         Abstracts must be submitted by January 31, 2019 to be considered. 
·         The sponsors will pay for the conference registration (including all conference meals and events) for one presenter for each accepted abstract. In addition, we will have limited funds available for travel subsidies (application included in submission form).
For more informationcontact our Executive Director Josh Abbott at

Good luck on your submission!

Prosthetic pain

“Feeling no pain” can be a euphemism for being drunk. However, there are some people for whom it’s not a euphemism and they literally feel no pain for one reason or another. One group of people who feel no pain are amputees and a researcher at Johns Hopkins University (Maryland, US) has found a way so they can feel pain again.

A June 20, 2018 news item on ScienceDaily provides an introduction to the research and to the reason for it,

Amputees often experience the sensation of a “phantom limb” — a feeling that a missing body part is still there.

That sensory illusion is closer to becoming a reality thanks to a team of engineers at the Johns Hopkins University that has created an electronic skin. When layered on top of prosthetic hands, this e-dermis brings back a real sense of touch through the fingertips.

“After many years, I felt my hand, as if a hollow shell got filled with life again,” says the anonymous amputee who served as the team’s principal volunteer tester.

Made of fabric and rubber laced with sensors to mimic nerve endings, e-dermis recreates a sense of touch as well as pain by sensing stimuli and relaying the impulses back to the peripheral nerves.

A June 20, 2018 Johns Hopkins University news release (also on EurekAlert), which originated the news item, explores the research in more depth,

“We’ve made a sensor that goes over the fingertips of a prosthetic hand and acts like your own skin would,” says Luke Osborn, a graduate student in biomedical engineering. “It’s inspired by what is happening in human biology, with receptors for both touch and pain.

“This is interesting and new,” Osborn said, “because now we can have a prosthetic hand that is already on the market and fit it with an e-dermis that can tell the wearer whether he or she is picking up something that is round or whether it has sharp points.”

The work – published June 20 in the journal Science Robotics – shows it is possible to restore a range of natural, touch-based feelings to amputees who use prosthetic limbs. The ability to detect pain could be useful, for instance, not only in prosthetic hands but also in lower limb prostheses, alerting the user to potential damage to the device.

Human skin contains a complex network of receptors that relay a variety of sensations to the brain. This network provided a biological template for the research team, which includes members from the Johns Hopkins departments of Biomedical Engineering, Electrical and Computer Engineering, and Neurology, and from the Singapore Institute of Neurotechnology.

Bringing a more human touch to modern prosthetic designs is critical, especially when it comes to incorporating the ability to feel pain, Osborn says.

“Pain is, of course, unpleasant, but it’s also an essential, protective sense of touch that is lacking in the prostheses that are currently available to amputees,” he says. “Advances in prosthesis designs and control mechanisms can aid an amputee’s ability to regain lost function, but they often lack meaningful, tactile feedback or perception.”

That is where the e-dermis comes in, conveying information to the amputee by stimulating peripheral nerves in the arm, making the so-called phantom limb come to life. The e-dermis device does this by electrically stimulating the amputee’s nerves in a non-invasive way, through the skin, says the paper’s senior author, Nitish Thakor, a professor of biomedical engineering and director of the Biomedical Instrumentation and Neuroengineering Laboratory at Johns Hopkins.

“For the first time, a prosthesis can provide a range of perceptions, from fine touch to noxious to an amputee, making it more like a human hand,” says Thakor, co-founder of Infinite Biomedical Technologies, the Baltimore-based company that provided the prosthetic hardware used in the study.

Inspired by human biology, the e-dermis enables its user to sense a continuous spectrum of tactile perceptions, from light touch to noxious or painful stimulus. The team created a “neuromorphic model” mimicking the touch and pain receptors of the human nervous system, allowing the e-dermis to electronically encode sensations just as the receptors in the skin would. Tracking brain activity via electroencephalography, or EEG, the team determined that the test subject was able to perceive these sensations in his phantom hand.

The researchers then connected the e-dermis output to the volunteer by using a noninvasive method known as transcutaneous electrical nerve stimulation, or TENS. In a pain-detection task, the team determined that the test subject and the prosthesis were able to experience a natural, reflexive reaction to both pain while touching a pointed object and non-pain when touching a round object.

The e-dermis is not sensitive to temperature–for this study, the team focused on detecting object curvature (for touch and shape perception) and sharpness (for pain perception). The e-dermis technology could be used to make robotic systems more human, and it could also be used to expand or extend to astronaut gloves and space suits, Osborn says.

The researchers plan to further develop the technology and better understand how to provide meaningful sensory information to amputees in the hopes of making the system ready for widespread patient use.

Johns Hopkins is a pioneer in the field of upper limb dexterous prostheses. More than a decade ago, the university’s Applied Physics Laboratory led the development of the advanced Modular Prosthetic Limb, which an amputee patient controls with the muscles and nerves that once controlled his or her real arm or hand.

In addition to the funding from Space@Hopkins, which fosters space-related collaboration across the university’s divisions, the team also received grants from the Applied Physics Laboratory Graduate Fellowship Program and the Neuroengineering Training Initiative through the National Institute of Biomedical Imaging and Bioengineering through the National Institutes of Health under grant T32EB003383.

The e-dermis was tested over the course of one year on an amputee who volunteered in the Neuroengineering Laboratory at Johns Hopkins. The subject frequently repeated the testing to demonstrate consistent sensory perceptions via the e-dermis. The team has worked with four other amputee volunteers in other experiments to provide sensory feedback.

Here’s a video about this work,

Sarah Zhang’s June 20, 2018 article for The Atlantic reveals a few more details while covering some of the material in the news release,

Osborn and his team added one more feature to make the prosthetic hand, as he puts it, “more lifelike, more self-aware”: When it grasps something too sharp, it’ll open its fingers and immediately drop it—no human control necessary. The fingers react in just 100 milliseconds, the speed of a human reflex. Existing prosthetic hands have a similar degree of theoretically helpful autonomy: If an object starts slipping, the hand will grasp more tightly. Ideally, users would have a way to override a prosthesis’s reflex, like how you can hold your hand on a stove if you really, really want to. After all, the whole point of having a hand is being able to tell it what to do.

Here’s a link to and a citation for the paper,

Prosthesis with neuromorphic multilayered e-dermis perceives touch and pain by Luke E. Osborn, Andrei Dragomir, Joseph L. Betthauser, Christopher L. Hunt, Harrison H. Nguyen, Rahul R. Kaliki, and Nitish V. Thakor. Science Robotics 20 Jun 2018: Vol. 3, Issue 19, eaat3818 DOI: 10.1126/scirobotics.aat3818

This paper is behind a paywall.

First CRISPR gene-edited babies? Ethics and the science story

Scientists, He Jiankui and Michael Deem, may have created the first human babies born after being subjected to CRISPR (clustered regularly interspaced short palindromic repeats) gene editing.  At this point, no one is entirely certain that these babies  as described actually exist since the information was made public in a rather unusual (for scientists) fashion.

The news broke on Sunday, November 25, 2018 through a number of media outlets none of which included journals associated with gene editing or high impact journals such as Cell, Nature, or Science.The news broke in MIT Technology Review and in Associated Press. Plus, this all happened just before the Second International Summit on Human Genome Editing (Nov. 27 – 29, 2018) in Hong Kong. He Jiankui was scheduled to speak today, Nov. 27, 2018.

Predictably, this news has caused quite a tizzy.

Breaking news

Antonio Regalado broke the news in a November 25, 2018  article for MIT [Massachusetts Institute of Technology] Technology Review (Note: Links have been removed),

According to Chinese medical documents posted online this month (here and here), a team at the Southern University of Science and Technology, in Shenzhen, has been recruiting couples in an effort to create the first gene-edited babies. They planned to eliminate a gene called CCR5 in hopes of rendering the offspring resistant to HIV, smallpox, and cholera.

The clinical trial documents describe a study in which CRISPR is employed to modify human embryos before they are transferred into women’s uteruses.

The scientist behind the effort, He Jiankui, did not reply to a list of questions about whether the undertaking had produced a live birth. Reached by telephone, he declined to comment.

However, data submitted as part of the trial listing shows that genetic tests have been carried out on fetuses as late as 24 weeks, or six months. It’s not known if those pregnancies were terminated, carried to term, or are ongoing.

Apparently He changed his mind because Marilynn Marchione in a November 26, 2018 article for the Associated Press confirms the news,

A Chinese researcher claims that he helped make the world’s first genetically edited babies — twin girls born this month whose DNA he said he altered with a powerful new tool capable of rewriting the very blueprint of life.

If true, it would be a profound leap of science and ethics.

A U.S. scientist [Dr. Michael Deem] said he took part in the work in China, but this kind of gene editing is banned in the United States because the DNA changes can pass to future generations and it risks harming other genes.

Many mainstream scientists think it’s too unsafe to try, and some denounced the Chinese report as human experimentation.

There is no independent confirmation of He’s claim, and it has not been published in a journal, where it would be vetted by other experts. He revealed it Monday [November 26, 2018] in Hong Kong to one of the organizers of an international conference on gene editing that is set to begin Tuesday [November 27, 2018], and earlier in exclusive interviews with The Associated Press.

“I feel a strong responsibility that it’s not just to make a first, but also make it an example,” He told the AP. “Society will decide what to do next” in terms of allowing or forbidding such science.

Some scientists were astounded to hear of the claim and strongly condemned it.

It’s “unconscionable … an experiment on human beings that is not morally or ethically defensible,” said Dr. Kiran Musunuru, a University of Pennsylvania gene editing expert and editor of a genetics journal.

“This is far too premature,” said Dr. Eric Topol, who heads the Scripps Research Translational Institute in California. “We’re dealing with the operating instructions of a human being. It’s a big deal.”

However, one famed geneticist, Harvard University’s George Church, defended attempting gene editing for HIV, which he called “a major and growing public health threat.”

“I think this is justifiable,” Church said of that goal.

h/t Cale Guthrie Weissman’s Nov. 26, 2018 article for Fast Company.

Diving into more detail

Ed Yong in a November 26, 2018 article for The Atlantic provides more details about the claims (Note: Links have been removed),

… “Two beautiful little Chinese girls, Lulu and Nana, came crying into the world as healthy as any other babies a few weeks ago,” He said in the first of five videos, posted yesterday {Nov. 25, 2018] to YouTube [link provided at the end of this section of the post]. “The girls are home now with their mom, Grace, and dad, Mark.” The claim has yet to be formally verified, but if true, it represents a landmark in the continuing ethical and scientific debate around gene editing.

Late last year, He reportedly enrolled seven couples in a clinical trial, and used their eggs and sperm to create embryos through in vitro fertilization. His team then used CRISPR to deactivate a single gene called CCR5 in the embryos, six of which they then implanted into mothers. CCR5 is a protein that the HIV virus uses to gain entry into human cells; by deactivating it, the team could theoretically reduce the risk of infection. Indeed, the fathers in all eight couples were HIV-positive.

Whether the experiment was successful or not, it’s intensely controversial. Scientists have already begun using CRISPR and other gene-editing technologies to alter human cells, in attempts to treat cancers, genetic disorders, and more. But in these cases, the affected cells stay within a person’s body. Editing an embryo [it’s often called, germline editing] is very different: It changes every cell in the body of the resulting person, including the sperm or eggs that would pass those changes to future generations. Such work is banned in many European countries, and prohibited in the United States. “I understand my work will be controversial, but I believe families need this technology and I’m willing to take the criticism for them,” He said.

“Was this a reasonable thing to do? I would say emphatically no,” says Paula Cannon of the University of Southern California. She and others have worked on gene editing, and particularly on trials that knock out CCR5 as a way to treat HIV. But those were attempts to treat people who were definitively sick and had run out of other options. That wasn’t the case with Nana and Lulu.

“The idea that being born HIV-susceptible, which is what the vast majority of humans are, is somehow a disease state that requires the extraordinary intervention of gene editing blows my mind,” says Cannon. “I feel like he’s appropriating this potentially valuable therapy as a shortcut to doing something in the sphere of gene editing. He’s either very naive or very cynical.”

“I want someone to make sure that it has happened,” says Hank Greely, an ethicist at Stanford University. If it hasn’t, that “would be a pretty bald-faced fraud,” but such deceptions have happened in the past. “If it is true, I’m disappointed. It’s reckless on safety grounds, and imprudent and stupid on social grounds.” He notes that a landmark summit in 2015 (which included Chinese researchers) and a subsequent major report from the National Academies of Science, Engineering, and Medicine both argued that “public participation should precede any heritable germ-line editing.” That is: Society needs to work out how it feels about making gene-edited babies before any babies are edited. Absent that consensus, He’s work is “waving a red flag in front of a bull,” says Greely. “It provokes not just the regular bio-Luddites, but also reasonable people who just wanted to talk it out.”

Societally, the creation of CRISPR-edited babies is a binary moment—a Rubicon that has been crossed. But scientifically, the devil is in the details, and most of those are still unknown.

CRISPR is still inefficient. [emphasis mine] The Chinese teams who first used it to edit human embryos only did so successfully in a small proportion of cases, and even then, they found worrying levels of “off-target mutations,” where they had erroneously cut parts of the genome outside their targeted gene. He, in his video, claimed that his team had thoroughly sequenced Nana and Lulu’s genomes and found no changes in genes other than CCR5.

That claim is impossible to verify in the absence of a peer-reviewed paper, or even published data of any kind. “The paper is where we see whether the CCR5 gene was properly edited, what effect it had at the cellular level, and whether [there were] any off-target effects,” said Eric Topol of the Scripps Research Institute. “It’s not just ‘it worked’ as a binary declaration.”

In the video, He said that using CRISPR for human enhancement, such as enhancing IQ or selecting eye color, “should be banned.” Speaking about Nana and Lulu’s parents, he said that they “don’t want a designer baby, just a child who won’t suffer from a disease that medicine can now prevent.”

But his rationale is questionable. Huang [Junjiu Huang of Sun Yat-sen University ], the first Chinese researcher to use CRISPR on human embryos, targeted the faulty gene behind an inherited disease called beta thalassemia. Mitalipov, likewise, tried to edit a gene called MYBPC3, whose faulty versions cause another inherited disease called hypertrophic cardiomyopathy (HCM). Such uses are still controversial, but they rank among the more acceptable applications for embryonic gene editing as ways of treating inherited disorders for which treatments are either difficult or nonexistent.

In contrast, He’s team disableda normal gene in an attempt to reduce the risk of a disease that neither child had—and one that can be controlled. There are already ways of preventing fathers from passing HIV to their children. There are antiviral drugs that prevent infections. There’s safe-sex education. “This is not a plague for which we have no tools,” says Cannon.

As Marilynn Marchione of the AP reports, early tests suggest that He’s editing was incomplete [emphasis mine], and at least one of the twins is a mosaic, where some cells have silenced copies of CCR5 and others do not. If that’s true, it’s unlikely that they would be significantly protected from HIV. And in any case, deactivating CCR5 doesn’t confer complete immunity, because some HIV strains can still enter cells via a different protein called CXCR4.

Nana and Lulu might have other vulnerabilities. …

It is also unclear if the participants in He’s trial were fully aware of what they were signing up for. [emphasis mine] The team’s informed-consent document describes their work as an “AIDS vaccine development project,” and while it describes CRISPR gene editing, it does so in heavily technical language. It doesn’t mention any of the risks of disabling CCR5, and while it does note the possibility of off-target effects, it also says that the “project team is not responsible for the risk.”

He owns two genetics companies, and his collaborator, Michael Deem of Rice University,  [emphasis mine] holds a small stake in, and sits on the advisory board of, both of them. The AP’s Marchione reports, “Both men are physics experts with no experience running human clinical trials.” [emphasis mine]

Yong’s article is well worth reading in its entirety. As for YouTube, here’s The He Lab’s webpage with relevant videos.


Gina Kolata, Sui-Lee Wee, and Pam Belluck writing in a Nov. 26, 2018 article for the New York Times chronicle some of the response to He’s announcement,

It is highly unusual for a scientist to announce a groundbreaking development without at least providing data that academic peers can review. Dr. He said he had gotten permission to do the work from the ethics board of the hospital Shenzhen Harmonicare, but the hospital, in interviews with Chinese media, denied being involved. Cheng Zhen, the general manager of Shenzhen Harmonicare, has asked the police to investigate what they suspect are “fraudulent ethical review materials,” according to the Beijing News.

The university that Dr. He is attached to, the Southern University of Science and Technology, said Dr. He has been on no-pay leave since February and that the school of biology believed that his project “is a serious violation of academic ethics and academic norms,” according to the state-run Beijing News.

In a statement late on Monday, China’s national health commission said it has asked the health commission in southern Guangdong province to investigate Mr. He’s claims.

“I think that’s completely insane,” said Shoukhrat Mitalipov, director of the Center for Embryonic Cell and Gene Therapy at Oregon Health and Science University. Dr. Mitalipov broke new ground last year by using gene editing to successfully remove a dangerous mutation from human embryos in a laboratory dish. [I wrote a three-part series about CRISPR, which included what was then the latest US news, Mitalipov’s announcement, along with a roundup of previous work in China. Links are at the end of this section.’

Dr. Mitalipov said that unlike his own work, which focuses on editing out mutations that cause serious diseases that cannot be prevented any other way, Dr. He did not do anything medically necessary. There are other ways to prevent H.I.V. infection in newborns.

Just three months ago, at a conference in late August on genome engineering at Cold Spring Harbor Laboratory in New York, Dr. He presented work on editing the CCR₅ gene in the embryos of nine couples.

At the conference, whose organizers included Jennifer Doudna, one of the inventors of Crispr technology, Dr. He gave a careful talk about something that fellow attendees considered squarely within the realm of ethically approved research. But he did not mention that some of those embryos had been implanted in a woman and could result in genetically engineered babies.

“What we now know is that as he was talking, there was a woman in China carrying twins,” said Fyodor Urnov, deputy director of the Altius Institute for Biomedical Sciences and a visiting researcher at the Innovative Genomics Institute at the University of California. “He had the opportunity to say ‘Oh and by the way, I’m just going to come out and say it, people, there’s a woman carrying twins.’”

“I would never play poker against Dr. He,” Dr. Urnov quipped.

Richard Hynes, a cancer researcher at the Massachusetts Institute of Technology, who co-led an advisory group on human gene editing for the National Academy of Sciences and the National Academy of Medicine, said that group and a similar organization in Britain had determined that if human genes were to be edited, the procedure should only be done to address “serious unmet needs in medical treatment, it had to be well monitored, it had to be well followed up, full consent has to be in place.”

It is not clear why altering genes to make people resistant to H.I.V. is “a serious unmet need.” Men with H.I.V. do not infect embryos. …

Dr. He got his Ph.D., from Rice University, in physics and his postdoctoral training, at Stanford, was with Stephen Quake, a professor of bioengineering and applied physics who works on sequencing DNA, not editing it.

Experts said that using Crispr would actually be quite easy for someone like Dr. He.

After coming to Shenzhen in 2012, Dr. He, at age 28, established a DNA sequencing company, Direct Genomics, and listed Dr. Quake on its advisory board. But, in a telephone interview on Monday, Dr. Quake said he was never associated with the company.

Deem, the US scientist who worked in China with He is currently being investigated (from a Nov. 26, 2018 article by Andrew Joseph in STAT),

Rice University said Monday that it had opened a “full investigation” into the involvement of one of its faculty members in a study that purportedly resulted in the creation of the world’s first babies born with edited DNA.

Michael Deem, a bioengineering professor at Rice, told the Associated Press in a story published Sunday that he helped work on the research in China.

Deem told the AP that he was in China when participants in the study consented to join the research. Deem also said that he had “a small stake” in and is on the scientific advisory boards of He’s two companies.

Megan Molteni in a Nov. 27, 2018 article for Wired admits she and her colleagues at the magazine may have dismissed CRISPR concerns about designer babies prematurely while shedding more light on this  latest development (Note: Links have been removed),

We said “don’t freak out,” when scientists first used Crispr to edit DNA in non-viable human embryos. When they tried it in embryos that could theoretically produce babies, we said “don’t panic.” Many years and years of boring bench science remain before anyone could even think about putting it near a woman’s uterus. Well, we might have been wrong. Permission to push the panic button granted.

Late Sunday night, a Chinese researcher stunned the world by claiming to have created the first human babies, a set of twins, with Crispr-edited DNA….

What’s perhaps most strange is not that He ignored global recommendations on conducting responsible Crispr research in humans. He also ignored his own advice to the world—guidelines that were published within hours of his transgression becoming public.

On Monday, He and his colleagues at Southern University of Science and Technology, in Shenzhen, published a set of draft ethical principles “to frame, guide, and restrict clinical applications that communities around the world can share and localize based on religious beliefs, culture, and public-health challenges.” Those principles included transparency and only performing the procedure when the risks are outweighed by serious medical need.

The piece appeared in the The Crispr Journal, a young publication dedicated to Crispr research, commentary, and debate. Rodolphe Barrangou, the journal’s editor in chief, where the peer-reviewed perspective appeared, says that the article was one of two that it had published recently addressing the ethical concerns of human germline editing, the other by a bioethicist at the University of North Carolina. Both papers’ authors had requested that their writing come out ahead of a major gene editing summit taking place this week in Hong Kong. When half-rumors of He’s covert work reached Barrangou over the weekend, his team discussed pulling the paper, but ultimately decided that there was nothing too solid to discredit it, based on the information available at the time.

Now Barrangou and his team are rethinking that decision. For one thing, He did not disclose any conflicts of interest, which is standard practice among respectable journals. It’s since become clear that not only is He at the helm of several genetics companies in China, He was actively pursuing controversial human research long before writing up a scientific and moral code to guide it.“We’re currently assessing whether the omission was a matter of ill-management or ill-intent,” says Barrangou, who added that the journal is now conducting an audit to see if a retraction might be warranted. …

“There are all sorts of questions these issues raise, but the most fundamental is the risk-benefit ratio for the babies who are going to be born,” says Hank Greely, an ethicist at Stanford University. “And the risk-benefit ratio on this stinks. Any institutional review board that approved it should be disbanded if not jailed.”

Reporting by Stat indicates that He may have just gotten in over his head and tried to cram a self-guided ethics education into a few short months. The young scientist—records indicate He is just 34—has a background in biophysics, with stints studying in the US at Rice University and in bioengineer Stephen Quake’s lab at Stanford. His resume doesn’t read like someone steeped deeply in the nuances and ethics of human research. Barrangou says that came across in the many rounds of edits He’s framework went through.

… China’s central government in Beijing has yet to come down one way or another. Condemnation would make He a rogue and a scientific outcast. Anything else opens the door for a Crispr IVF cottage industry to emerge in China and potentially elsewhere. “It’s hard to imagine this was the only group in the world doing this,” says Paul Knoepfler, a stem cell researcher at UC Davis who wrote a book on the future of designer babies called GMO Sapiens. “Some might say this broke the ice. Will others forge ahead and go public with their results or stop what they’re doing and see how this plays out?”

Here’s some of the very latest information with the researcher attempting to explain himself.

What does He have to say?

After He’s appearance at the Second International Summit on Human Genome Editing today, Nov. 27, 2018, David Cyranoski produced this article for Nature,

He Jiankui, the Chinese scientist who claims to have helped produce the first people born with edited genomes — twin girls — appeared today at a gene-editing summit in Hong Kong to explain his experiment. He gave his talk amid threats of legal action and mounting questions, from the scientific community and beyond, about the ethics of his work and the way in which he released the results.

He had never before presented his work publicly outside of a handful of videos he posted on YouTube. Scientists welcomed the fact that he appeared at all — but his talk left many hungry for more answers, and still not completely certain that He has achieved what he claims.

“There’s no reason not to believe him,” says Robin Lovell-Badge, a developmental biologist at the Francis Crick Institute in London. “I’m just not completely convinced.”

Lovell-Badge, like others at the conference, says that an independent body should confirm the test results by performing an in-depth comparison of the parents’ and childrens’ genes.

Many scientists faulted He for a lack of transparency and the seemingly cavalier nature in which he embarked on such a landmark, and potentially risky, project.

“I’m happy he came but I was really horrified and stunned when he described the process he used,” says Jennifer Doudna, a biochemist at the University of California, Berkeley and a pioneer of the CRISPR/Cas-9 gene-editing technique that He used. “It was so inappropriate on so many levels.”

He seemed shaky approaching the stage and nervous during the talk. “I think he was scared,” says Matthew Porteus, who researches genome-editing at Stanford University in California and co-hosted a question-and-answer session with He after his presentation. Porteus attributes this either to the legal pressures that He faces or the mounting criticism from the scientists and media he was about to address.

He’s talk leaves a host of other questions unanswered, including whether the prospective parents were properly informed of the risks; why He selected CCR5 when there are other, proven ways to prevent HIV; why he chose to do the experiment with couples in which the fathers have HIV, rather than mothers who have a higher chance of passing the virus on to their children; and whether the risks of knocking out CCR5 — a gene normally present in people, which could have necessary but still unknown functions — outweighed the benefits in this case.

In the discussion following He’s talk, one scientist asked why He proceeded with the experiments despite the clear consensus among scientists worldwide that such research shouldn’t be done. He didn’t answer the question.

He’s attempts to justify his actions mainly fell flat. In response to questions about why the science community had not been informed of the experiments before the first women were impregnated, he cited presentations that he gave last year at meetings at the University of California, Berkeley, and at the Cold Spring Harbor Laboratory in New York. But Doudna, who organized the Berkeley meeting, says He did not present anything that showed he was ready to experiment in people. She called his defence “disingenuous at best”.

He also said he discussed the human experiment with unnamed scientists in the United States. But Porteus says that’s not enough for such an extraordinary experiment: “You need feedback not from your two closest friends but from the whole community.” …

Pressure was mounting on He ahead of the presentation. On 27 November, the Chinese national health commission ordered the Guangdong health commission, in the province where He’s university is located, to investigate.

On the same day, the Chinese Academy of Sciences issued a statement condemning his work, and the Genetics Society of China and the Chinese Society for Stem Cell Research jointly issued a statement saying the experiment “violates internationally accepted ethical principles regulating human experimentation and human rights law”.

The hospital cited in China’s clinical-trial registry as the that gave ethical approval for He’s work posted a press release on 27 November saying it did not give any approval. It questioned the signatures on the approval form and said that the hospital’s medical-ethics committee never held a meeting related to He’s research. The hospital, which itself is under investigation by the Shenzhen health authorities following He’s revelations, wrote: “The Company does not condone the means of the Claimed Project, and has reservations as to the accuracy, reliability and truthfulness of its contents and results.”

He has not yet responded to requests for comment on these statements and investigations, nor on why the hospital was listed in the registry and the claim of apparent forged signatures.

Alice Park’s Nov. 26, 2018 article for Time magazine includes an embedded video of He’s Nov. 27, 2018 presentation at the summit meeting.

What about the politics?

Mara Hvistendahl’s Nov. 27, 2018 article about this research for poses some geopolitical questions (Note: Links have been removed),

The informed consent agreement for He Jiankui’s experiment describes it as an “AIDS vaccine development project” and used highly technical language to describe the procedure that patients would undergo. If the reality for some Chinese patients is that such agreements are glossed over, densely written, or never read, the reality for some researchers working in the country is that the appeal of cutting-edge trials is too great to resist. It is not just Chinese scientists who can be blinded by the lure of quick breakthroughs. Several of the most notable breaches of informed consent on the mainland have involved Western researchers or co-authors. … When people say that the usual rules don’t apply in China, they are really referring to authoritarian science, not some alternative communitarian ethics.

For the many scientists in China who adhere to recognized international standards, the incident comes as a disgrace. He Jiankui now faces an ethics investigation from provincial health authorities, and his institution, Southern University of Science and Technology, was quick to issue a statement noting that He was on unpaid leave. …

It would seem that US [and from elsewhere]* scientists wanting to avoid pesky ethics requirements in the US have found that going to China could be the answer to their problems. I gather it’s not just big business that prefers deregulated environments.

Guillaume Levrier’s  (he’ studying for a PhD at the Universté Sorbonne Paris Cité) November 16, 2018 essay for The Conversation sheds some light on political will and its impact on science (Note: Links have been removed),

… China has entered a “genome editing” race among great scientific nations and its progress didn’t come out of nowhere. China has invested heavily in the natural-sciences sector over the past 20 years. The Ninth Five-Year Plan (1996-2001) mentioned the crucial importance of biotechnologies. The current Thirteenth Five-Year Plan is even more explicit. It contains a section dedicated to “developing efficient and advanced biotechnologies” and lists key sectors such as “genome-editing technologies” intended to “put China at the bleeding edge of biotechnology innovation and become the leader in the international competition in this sector”.

Chinese embryo research is regulated by a legal framework, the “technical norms on human-assisted reproductive technologies”, published by the Science and Health Ministries. The guidelines theoretically forbid using sperm or eggs whose genome have been manipulated for procreative purposes. However, it’s hard to know how much value is actually placed on this rule in practice, especially in China’s intricate institutional and political context.

In theory, three major actors have authority on biomedical research in China: the Science and Technology Ministry, the Health Ministry, and the Chinese Food and Drug Administration. In reality, other agents also play a significant role. Local governments interpret and enforce the ministries’ “recommendations”, and their own interpretations can lead to significant variations in what researchers can and cannot do on the ground. The Chinese National Academy of Medicine is also a powerful institution that has its own network of hospitals, universities and laboratories.

Another prime actor is involved: the health section of the People’s Liberation Army (PLA), which has its own biomedical faculties, hospitals and research labs. The PLA makes its own interpretations of the recommendations and has proven its ability to work with the private sector on gene editing projects. …

One other thing from Levrier’s essay,

… And the media timing is just a bit too perfect, …

Do read the essay; there’s a twist at the end.

Final thoughts and some links

If I read this material rightly, there are suspicions there may be more of this work being done in China and elsewhere. In short, we likely don’t have the whole story.

As for the ethical issues, this is a discussion among experts only, so far. The great unwashed (thee and me) are being left at the wayside. Sure, we’ll be invited to public consultations, one day,  after the big decisions have been made.

Anyone who’s read up on the history of science will tell you this kind of breach is very common at the beginning. Richard Holmes’  2008 book, ‘The Age of Wonder: How the Romantic Generation Discovered the Beauty and Terror of Science’ recounts stories of early scientists (European science) who did crazy things. Some died, some shortened their life spans; and, some irreversibly damaged their health.  They also experimented on other people. Informed consent had not yet been dreamed up.

In fact, I remember reading somewhere that the largest human clinical trial in history was held in Canada. The small pox vaccine was highly contested in the US but the Canadian government thought it was a good idea so they offered US scientists the option of coming here to vaccinate Canadian babies. This was in the 1950s and the vaccine seems to have been administered almost universally. That was a lot of Canadian babies. Thankfully, it seems to have worked out but it does seem mind-boggling today.

For all the indignation and shock we’re seeing, this is not the first time nor will it be the last time someone steps over a line in order to conduct scientific research. And, that is the eternal problem.

Meanwhile I think some of the real action regarding CRISPR and germline editing is taking place in the field (pun!) of agriculture:

My Nov. 27, 2018 posting titled: ‘Designer groundcherries by CRISPR (clustered regularly interspaced short palindromic repeats)‘ and a more disturbing Nov. 27, 2018 post titled: ‘Agriculture and gene editing … shades of the AquAdvantage salmon‘. That second posting features a company which is trying to sell its gene-editing services to farmers who would like cows that  never grow horns and pigs that never reach puberty.

Then there’s this ,

The Genetic Revolution‘, a documentary that offers relatively up-to-date information about gene editing, which was broadcast on Nov. 11, 2018 as part of The Nature of Things series on CBC (Canadian Broadcasting Corporation).

My July 17, 2018 posting about research suggesting that scientists hadn’t done enough research on possible effects of CRISPR editing titled: ‘The CRISPR ((clustered regularly interspaced short palindromic repeats)-CAS9 gene-editing technique may cause new genetic damage kerfuffle’.

My 2017 three-part series on CRISPR and germline editing:

CRISPR and editing the germline in the US (part 1 of 3): In the beginning

CRISPR and editing the germline in the US (part 2 of 3): ‘designer babies’?

CRISPR and editing the germline in the US (part 3 of 3): public discussions and pop culture

There you have it.

Added on November 30, 2018: David Cyanowski has written one final article (Nov. 30, 2018 for Nature) about He and the Second International Summit on Human Genome Editing. He did not make his second scheduled appearance at the summit, returning to China before the summit concluded. He was rebuked in a statement produced by the Summit’s organizing committee at the end of the three-day meeting. The situation with regard to his professional status in China is ambiguous. Cyanowski ends his piece with the information that the third summit will take place in London (likely in the UK) in 2021. I encourage you to read Cyanowski’s Nov. 30, 2018 article in its entirety; it’s not long.

Added on Dec. 3, 2018: The story continues. Ed Yong has written a summary of the issues to date in a Dec. 3, 2018 article for The Atlantic (even if you know the story ift’s eyeopening to see all the parts put together.

J. Benjamin Hurlbut, Associate Professor of Life Sciences at Arizona State University (ASU) and Jason Scott Robert, Director of the Lincoln Center for Applied Ethics at Arizona State University have written a provocative (and true) Dec. 3, 2018 essay titled, CRISPR babies raise an uncomfortable reality – abiding by scientific standards doesn’t guarantee ethical research, for The Conversation. h/t

*[and from elsewhere] added January 17, 2019.

Added on January 23, 2019: He has been fired by his university (Southern University of Science and Technology in Shenzhen) as announced on January 21, 2019.  David Cyranoski provides a details accounting in his January 22, 2019 article for Nature.

I found it at the movies: a commentary on/review of “Films from the Future”

Kudos to anyone who recognized the reference to Pauline Kael (she changed film criticism forever) and her book “I Lost it at the Movies.” Of course, her book title was a bit of sexual innuendo, quite risqué for an important film critic in 1965 but appropriate for a period (the 1960s) associated with a sexual revolution. (There’s more about the 1960’s sexual revolution in the US along with mention of a prior sexual revolution in the 1920s in this Wikipedia entry.)

The title for this commentary is based on an anecdote from Dr. Andrew Maynard’s (director of the Arizona State University [ASU] Risk Innovation Lab) popular science and technology book, “Films from the Future: The Technology and Morality of Sci-Fi Movies.”

The ‘title-inspiring’ anecdote concerns Maynard’s first viewing of ‘2001: A Space Odyssey, when as a rather “bratty” 16-year-old who preferred to read science fiction, he discovered new ways of seeing and imaging the world. Maynard isn’t explicit about when he became a ‘techno nerd’ or how movies gave him an experience books couldn’t but presumably at 16 he was already gearing up for a career in the sciences. That ‘movie’ revelation received in front of a black and white television on January 1,1982 eventually led him to write, “Films from the Future.” (He has a PhD in physics which he is now applying to the field of risk innovation. For a more detailed description of Dr. Maynard and his work, there’s his ASU profile webpage and, of course, the introduction to his book.)

The book is quite timely. I don’t know how many people have noticed but science and scientific innovation is being covered more frequently in the media than it has been in many years. Science fairs and festivals are being founded on what seems to be a daily basis and you can now find science in art galleries. (Not to mention the movies and television where science topics are covered in comic book adaptations, in comedy, and in standard science fiction style.) Much of this activity is centered on what’s called ’emerging technologies’. These technologies are why people argue for what’s known as ‘blue sky’ or ‘basic’ or ‘fundamental’ science for without that science there would be no emerging technology.

Films from the Future

Isn’t reading the Table of Contents (ToC) the best way to approach a book? (From Films from the Future; Note: The formatting has been altered),

Table of Contents
Chapter One
In the Beginning 14
Beginnings 14
Welcome to the Future 16
The Power of Convergence 18
Socially Responsible Innovation 21
A Common Point of Focus 25
Spoiler Alert 26
Chapter Two
Jurassic Park: The Rise of Resurrection Biology 27
When Dinosaurs Ruled the World 27
De-Extinction 31
Could We, Should We? 36
The Butterfly Effect 39
Visions of Power 43
Chapter Three
Never Let Me Go: A Cautionary Tale of Human Cloning 46
Sins of Futures Past 46
Cloning 51
Genuinely Human? 56
Too Valuable to Fail? 62
Chapter Four
Minority Report: Predicting Criminal Intent 64
Criminal Intent 64
The “Science” of Predicting Bad Behavior 69
Criminal Brain Scans 74
Machine Learning-Based Precognition 77
Big Brother, Meet Big Data 79
Chapter Five
Limitless: Pharmaceutically-enhanced Intelligence 86
A Pill for Everything 86
The Seduction of Self-Enhancement 89
Nootropics 91
If You Could, Would You? 97
Privileged Technology 101
Our Obsession with Intelligence 105
Chapter Six
Elysium: Social Inequity in an Age of Technological
Extremes 110
The Poor Shall Inherit the Earth 110
Bioprinting Our Future Bodies 115
The Disposable Workforce 119
Living in an Automated Future 124
Chapter Seven
Ghost in the Shell: Being Human in an
Augmented Future 129
Through a Glass Darkly 129
Body Hacking 135
More than “Human”? 137
Plugged In, Hacked Out 142
Your Corporate Body 147
Chapter Eight
Ex Machina: AI and the Art of Manipulation 154
Plato’s Cave 154
The Lure of Permissionless Innovation 160
Technologies of Hubris 164
Superintelligence 169
Defining Artificial Intelligence 172
Artificial Manipulation 175
Chapter Nine
Transcendence: Welcome to the Singularity 180
Visions of the Future 180
Technological Convergence 184
Enter the Neo-Luddites 190
Techno-Terrorism 194
Exponential Extrapolation 200
Make-Believe in the Age of the Singularity 203
Chapter Ten
The Man in the White Suit: Living in a Material World 208
There’s Plenty of Room at the Bottom 208
Mastering the Material World 213
Myopically Benevolent Science 220
Never Underestimate the Status Quo 224
It’s Good to Talk 227
Chapter Eleven
Inferno: Immoral Logic in an Age of
Genetic Manipulation 231
Decoding Make-Believe 231
Weaponizing the Genome 234
Immoral Logic? 238
The Honest Broker 242
Dictating the Future 248
Chapter Twelve
The Day After Tomorrow: Riding the Wave of
Climate Change 251
Our Changing Climate 251
Fragile States 255
A Planetary “Microbiome” 258
The Rise of the Anthropocene 260
Building Resiliency 262
Geoengineering the Future 266
Chapter Thirteen
Contact: Living by More than Science Alone 272
An Awful Waste of Space 272
More than Science Alone 277
Occam’s Razor 280
What If We’re Not Alone? 283
Chapter Fourteen
Looking to the Future 288
Acknowledgments 293

The ToC gives the reader a pretty clue as to where the author is going with their book and Maynard explains how he chose his movies in his introductory chapter (from Films from the Future),

“There are some quite wonderful science fiction movies that didn’t make the cut because they didn’t fit the overarching narrative (Blade Runner and its sequel Blade Runner 2049, for instance, and the first of the Matrix trilogy). There are also movies that bombed with the critics, but were included because they ably fill a gap in the bigger story around emerging and converging technologies. Ultimately, the movies that made the cut were chosen because, together, they create an overarching narrative around emerging trends in biotechnologies, cybertechnologies, and materials-based technologies, and they illuminate a broader landscape around our evolving relationship with science and technology. And, to be honest, they are all movies that I get a kick out of watching.” (p. 17)

Jurassic Park (Chapter Two)

Dinosaurs do not interest me—they never have. Despite my profound indifference I did see the movie, Jurassic Park, when it was first released (someone talked me into going). And, I am still profoundly indifferent. Thankfully, Dr. Maynard finds meaning and a connection to current trends in biotechnology,

Jurassic Park is unabashedly a movie about dinosaurs. But it’s also a movie about greed, ambition, genetic engineering, and human folly—all rich pickings for thinking about the future, and what could possibly go wrong. (p. 28)

What really stands out with Jurassic Park, over twenty-five years later, is how it reveals a very human side of science and technology. This comes out in questions around when we should tinker with technology and when we should leave well enough alone. But there is also a narrative here that appears time and time again with the movies in this book, and that is how we get our heads around the sometimes oversized roles mega-entrepreneurs play in dictating how new tech is used, and possibly abused. These are all issues that are just as relevant now as they were in 1993, and are front and center of ensuring that the technologyenabled future we’re building is one where we want to live, and not one where we’re constantly fighting for our lives.  (pp. 30-1)

He also describes a connection to current trends in biotechnology,


In a far corner of Siberia, two Russians—Sergey Zimov and his son Nikita—are attempting to recreate the Ice Age. More precisely, their vision is to reconstruct the landscape and ecosystem of northern Siberia in the Pleistocene, a period in Earth’s history that stretches from around two and a half million years ago to eleven thousand years ago. This was a time when the environment was much colder than now, with huge glaciers and ice sheets flowing over much of the Earth’s northern hemisphere. It was also a time when humans
coexisted with animals that are long extinct, including saber-tooth cats, giant ground sloths, and woolly mammoths.

The Zimovs’ ambitions are an extreme example of “Pleistocene rewilding,” a movement to reintroduce relatively recently extinct large animals, or their close modern-day equivalents, to regions where they were once common. In the case of the Zimovs, the
father-and-son team believe that, by reconstructing the Pleistocene ecosystem in the Siberian steppes and elsewhere, they can slow down the impacts of climate change on these regions. These areas are dominated by permafrost, ground that never thaws through
the year. Permafrost ecosystems have developed and survived over millennia, but a warming global climate (a theme we’ll come back to in chapter twelve and the movie The Day After Tomorrow) threatens to catastrophically disrupt them, and as this happens, the impacts
on biodiversity could be devastating. But what gets climate scientists even more worried is potentially massive releases of trapped methane as the permafrost disappears.

Methane is a powerful greenhouse gas—some eighty times more effective at exacerbating global warming than carbon dioxide— and large-scale releases from warming permafrost could trigger catastrophic changes in climate. As a result, finding ways to keep it in the ground is important. And here the Zimovs came up with a rather unusual idea: maintaining the stability of the environment by reintroducing long-extinct species that could help prevent its destruction, even in a warmer world. It’s a wild idea, but one that has some merit.8 As a proof of concept, though, the Zimovs needed somewhere to start. And so they set out to create a park for deextinct Siberian animals: Pleistocene Park.9

Pleistocene Park is by no stretch of the imagination a modern-day Jurassic Park. The dinosaurs in Hammond’s park date back to the Mesozoic period, from around 250 million years ago to sixty-five million years ago. By comparison, the Pleistocene is relatively modern history, ending a mere eleven and a half thousand years ago. And the vision behind Pleistocene Park is not thrills, spills, and profit, but the serious use of science and technology to stabilize an increasingly unstable environment. Yet there is one thread that ties them together, and that’s using genetic engineering to reintroduce extinct species. In this case, the species in question is warm-blooded and furry: the woolly mammoth.

The idea of de-extinction, or bringing back species from extinction (it’s even called “resurrection biology” in some circles), has been around for a while. It’s a controversial idea, and it raises a lot of tough ethical questions. But proponents of de-extinction argue
that we’re losing species and ecosystems at such a rate that we can’t afford not to explore technological interventions to help stem the flow.

Early approaches to bringing species back from the dead have involved selective breeding. The idea was simple—if you have modern ancestors of a recently extinct species, selectively breeding specimens that have a higher genetic similarity to their forebears can potentially help reconstruct their genome in living animals. This approach is being used in attempts to bring back the aurochs, an ancestor of modern cattle.10 But it’s slow, and it depends on
the fragmented genome of the extinct species still surviving in its modern-day equivalents.

An alternative to selective breeding is cloning. This involves finding a viable cell, or cell nucleus, in an extinct but well-preserved animal and growing a new living clone from it. It’s definitely a more appealing route for impatient resurrection biologists, but it does mean getting your hands on intact cells from long-dead animals and devising ways to “resurrect” these, which is no mean feat. Cloning has potential when it comes to recently extinct species whose cells have been well preserved—for instance, where the whole animal has become frozen in ice. But it’s still a slow and extremely limited option.

Which is where advances in genetic engineering come in.

The technological premise of Jurassic Park is that scientists can reconstruct the genome of long-dead animals from preserved DNA fragments. It’s a compelling idea, if you think of DNA as a massively long and complex instruction set that tells a group of biological molecules how to build an animal. In principle, if we could reconstruct the genome of an extinct species, we would have the basic instruction set—the biological software—to reconstruct
individual members of it.

The bad news is that DNA-reconstruction-based de-extinction is far more complex than this. First you need intact fragments of DNA, which is not easy, as DNA degrades easily (and is pretty much impossible to obtain, as far as we know, for dinosaurs). Then you
need to be able to stitch all of your fragments together, which is akin to completing a billion-piece jigsaw puzzle without knowing what the final picture looks like. This is a Herculean task, although with breakthroughs in data manipulation and machine learning,
scientists are getting better at it. But even when you have your reconstructed genome, you need the biological “wetware”—all the stuff that’s needed to create, incubate, and nurture a new living thing, like eggs, nutrients, a safe space to grow and mature, and so on. Within all this complexity, it turns out that getting your DNA sequence right is just the beginning of translating that genetic code into a living, breathing entity. But in some cases, it might be possible.

In 2013, Sergey Zimov was introduced to the geneticist George Church at a conference on de-extinction. Church is an accomplished scientist in the field of DNA analysis and reconstruction, and a thought leader in the field of synthetic biology (which we’ll come
back to in chapter nine). It was a match made in resurrection biology heaven. Zimov wanted to populate his Pleistocene Park with mammoths, and Church thought he could see a way of
achieving this.

What resulted was an ambitious project to de-extinct the woolly mammoth. Church and others who are working on this have faced plenty of hurdles. But the technology has been advancing so fast that, as of 2017, scientists were predicting they would be able to reproduce the woolly mammoth within the next two years.

One of those hurdles was the lack of solid DNA sequences to work from. Frustratingly, although there are many instances of well preserved woolly mammoths, their DNA rarely survives being frozen for tens of thousands of years. To overcome this, Church and others
have taken a different tack: Take a modern, living relative of the mammoth, and engineer into it traits that would allow it to live on the Siberian tundra, just like its woolly ancestors.

Church’s team’s starting point has been the Asian elephant. This is their source of base DNA for their “woolly mammoth 2.0”—their starting source code, if you like. So far, they’ve identified fifty plus gene sequences they think they can play with to give their modern-day woolly mammoth the traits it would need to thrive in Pleistocene Park, including a coat of hair, smaller ears, and a constitution adapted to cold.

The next hurdle they face is how to translate the code embedded in their new woolly mammoth genome into a living, breathing animal. The most obvious route would be to impregnate a female Asian elephant with a fertilized egg containing the new code. But Asian elephants are endangered, and no one’s likely to allow such cutting edge experimentation on the precious few that are still around, so scientists are working on an artificial womb for their reinvented woolly mammoth. They’re making progress with mice and hope to crack the motherless mammoth challenge relatively soon.

It’s perhaps a stretch to call this creative approach to recreating a species (or “reanimation” as Church refers to it) “de-extinction,” as what is being formed is a new species. … (pp. 31-4)

This selection illustrates what Maynard does so very well throughout the book where he uses each film as a launching pad for a clear, readable description of relevant bits of science so you understand why the premise was likely, unlikely, or pure fantasy while linking it to contemporary practices, efforts, and issues. In the context of Jurassic Park, Maynard goes on to raise some fascinating questions such as: Should we revive animals rendered extinct (due to obsolescence or inability to adapt to new conditions) when we could develop new animals?

General thoughts

‘Films for the Future’ offers readable (to non-scientific types) science, lively writing, and the occasional ‘memorish’ anecdote. As well, Dr. Maynard raises the curtain on aspects of the scientific enterprise that most of us do not get to see.  For example, the meeting  between Sergey Zimov and George Church and how it led to new ‘de-extinction’ work’. He also describes the problems that the scientists encountered and are encountering. This is in direct contrast to how scientific work is usually presented in the news media as one glorious breakthrough after the next.

Maynard does discuss the issues of social inequality and power and ownership. For example, who owns your transplant or data? Puzzlingly, he doesn’t touch on the current environment where scientists in the US and elsewhere are encouraged/pressured to start up companies commercializing their work.

Nor is there any mention of how universities are participating in this grand business experiment often called ‘innovation’. (My March 15, 2017 posting describes an outcome for the CRISPR [gene editing system] patent fight taking place between Harvard University’s & MIT’s [Massachusetts Institute of Technology] Broad Institute vs the University of California at Berkeley and my Sept. 11, 2018 posting about an art/science exhibit in Vancouver [Canada] provides an update for round 2 of the Broad Institute vs. UC Berkeley patent fight [scroll down about 65% of the way.) *To read about how my ‘cultural blindness’ shows up here scroll down to the single asterisk at the end.*

There’s a foray through machine-learning and big data as applied to predictive policing in Maynard’s ‘Minority Report’ chapter (my November 23, 2017 posting describes Vancouver’s predictive policing initiative [no psychics involved], the first such in Canada). There’s no mention of surveillance technology, which if I recall properly was part of the future environment, both by the state and by corporations. (Mia Armstrong’s November 15, 2018 article for Slate on Chinese surveillance being exported to Venezuela provides interesting insight.)

The gaps are interesting and various. This of course points to a problem all science writers have when attempting an overview of science. (Carl Zimmer’s latest, ‘She Has Her Mother’s Laugh: The Powers, Perversions, and Potential of Heredity’] a doorstopping 574 pages, also has some gaps despite his focus on heredity,)

Maynard has worked hard to give an comprehensive overview in a remarkably compact 279 pages while developing his theme about science and the human element. In other words, science is not monolithic; it’s created by human beings and subject to all the flaws and benefits that humanity’s efforts are always subject to—scientists are people too.

The readership for ‘Films from the Future’ spans from the mildly interested science reader to someone like me who’s been writing/blogging about these topics (more or less) for about 10 years. I learned a lot reading this book.

Next time, I’m hopeful there’ll be a next time, Maynard might want to describe the parameters he’s set for his book in more detail that is possible in his chapter headings. He could have mentioned that he’s not a cinéaste so his descriptions of the movies are very much focused on the story as conveyed through words. He doesn’t mention colour palates, camera angles, or, even, cultural lenses.

Take for example, his chapter on ‘Ghost in the Shell’. Focused on the Japanese animation film and not the live action Hollywood version he talks about human enhancement and cyborgs. The Japanese have a different take on robots, inanimate objects, and, I assume, cyborgs than is found in Canada or the US or Great Britain, for that matter (according to a colleague of mine, an Englishwoman who lived in Japan for ten or more years). There’s also the chapter on the Ealing comedy, The Man in The White Suit, an English film from the 1950’s. That too has a cultural (as well as, historical) flavour but since Maynard is from England, he may take that cultural flavour for granted. ‘Never let me go’ in Chapter Two was also a UK production, albeit far more recent than the Ealing comedy and it’s interesting to consider how a UK production about cloning might differ from a US or Chinese or … production on the topic. I am hearkening back to Maynard’s anecdote about movies giving him new ways of seeing and imagining the world.

There’s a corrective. A couple of sentences in Maynard’s introductory chapter cautioning that in depth exploration of ‘cultural lenses’ was not possible without expanding the book to an unreadable size followed by a sentence in each of the two chapters that there are cultural differences.

One area where I had a significant problem was with regard to being “programmed” and having  “instinctual” behaviour,

As a species, we are embarrassingly programmed to see “different” as “threatening,” and to take instinctive action against it. It’s a trait that’s exploited in many science fiction novels and movies, including those in this book. If we want to see the rise of increasingly augmented individuals, we need to be prepared for some social strife. (p. 136)

These concepts are much debated in the social sciences and there are arguments for and against ‘instincts regarding strangers and their possible differences’. I gather Dr. Maynard hies to the ‘instinct to defend/attack’ school of thought.

One final quandary, there was no sex and I was expecting it in the Ex Machina chapter, especially now that sexbots are about to take over the world (I exaggerate). Certainly, if you’re talking about “social strife,” then sexbots would seem to be fruitful line of inquiry, especially when there’s talk of how they could benefit families (my August 29, 2018 posting). Again, there could have been a sentence explaining why Maynard focused almost exclusively in this chapter on the discussions about artificial intelligence and superintelligence.

Taken in the context of the book, these are trifling issues and shouldn’t stop you from reading Films from the Future. What Maynard has accomplished here is impressive and I hope it’s just the beginning.

Final note

Bravo Andrew! (Note: We’ve been ‘internet acquaintances/friends since the first year I started blogging. When I’m referring to him in his professional capacity, he’s Dr. Maynard and when it’s not strictly in his professional capacity, it’s Andrew. For this commentary/review I wanted to emphasize his professional status.)

If you need to see a few more samples of Andrew’s writing, there’s a Nov. 15, 2018 essay on The Conversation, Sci-fi movies are the secret weapon that could help Silicon Valley grow up and a Nov. 21, 2018 article on, The True Cost of Stain-Resistant Pants; The 1951 British comedy The Man in the White Suit anticipated our fears about nanotechnology. Enjoy.

****Added at 1700 hours on Nov. 22, 2018: You can purchase Films from the Future here.

*Nov. 23, 2018: I should have been more specific and said ‘academic scientists’. In Canada, the great percentage of scientists are academic. It’s to the point where the OECD (Organization for Economic Cooperation and Development) has noted that amongst industrialized countries, Canada has very few industrial scientists in comparison to the others.

All about gene editing, sexual reproduction, and the arts (an October 27, 2018 ArtSci Salon event in Toronto, Canada)

This ArtSci Salon event is part of the third world congress, GeNeDis (Genetics, Geriatrics, and Neurodegenerative Diseases Research). GeNeDis 2018 was organized by The Laboratory of Bioinformatics and Human Electrophysiology, Department of Informatics of the Ionian University (Corfu Greece) in cooperation with the Fields Institute (for Research in Mathematical Sciences) at the University of Toronto (Ontario, Canada) and Wilfrid Laurier University (Waterloo Ontario).

The ArtSci Salon will be presenting (from the ArtSci Salon GeNeDis event page) Note: Read carefully as this is a multi-pronged event,

GeNeDis Panel and Exhibition – Gene Editing, sexual reproduction and the arts: Oct 27, 2018

ArtSci salon is proud to present an event to explore the entangled issues of sex and sexual fantasy, sexual reproduction and sexual regulation, fertility and sexual technologies. We invited artists and scholars to address these themes using their preferred approach: the result is a thought provoking series which interrogates and imagines these issues through human/non-human sexual fantasies, interrogates them by means of modified gynaecological instruments, rewrites potential scenarios as enhanced and/or elderly humans, or offers unexpected ways to hack sex right here, right now.

Our goal is not just to imagine how media, technological enhancement, gene editing and medical treatments will transform our idea of sex and our sexuality as human beings and as part of the wide non-human world that surrounds us. It is also to think of how creative/critical initiatives may facilitate a sustained dialogue to help us cope with unresolved issues in the present. Interdisciplinary so!

The event will be accompanied by an exhibition on display Oct 18-Nov.8 in the Koffler Students Centre Cabinets, University of Toronto

Panel discussion

Gene editing, sexual reproduction and the arts: the present, the future and the imagined

ArtSci Salon will participate in the scientific conference GeNeDis (Genetics, Geriatrics, and Neurodegenerative Diseases Research) with a special panel addressing the topic of gene editing and sexual reproduction from a sciart perspective. The discussion will be preceded by the official opening of an exhibition illustrating how present issues in gynaecology and sexual regulation, hormonal management, human enhancement and sexual and cultural identity may be addressed, redressed, hacked and reimagined through the arts.

The Panel will be followed by a reception

Chair: Roberta Buiani, ArtSci Salon, Fields Institute
Speakers: Byron Rich, Samira Daneshvar, Adam Zaretsky & Dolores Steinman.

Saturday, Oct 27,

Lennox Hall
77 Adelaide Street W.

please, RSVP here 

For a little more detail about the event, you can check an Oct. 19, 2018 news item in Clot magazine,

On October 27th [2018], interdisciplinary group ArtSci Salon will present a panel discussion addressing the topic of gene editing and sexual reproduction from a sciart perspective. Preceding the discussion will be the official opening of an exhibition featuring the work of four of the speakers; a show that reimagines issues relating to gynaecology, sexual regulation, hormonal management and cultural identity through the arts.

During the conversation itself, the panel will focus on the current status of genome editing, presenting a nuanced alternative to sensationalist media narratives that often frame genome editing as a set of dichotomized future predictions, either utopian or dystopian. Stepping back into the present, the speakers will rethink the implications of genome editing through a creative lens, exploring the intersection of scientific and artistic interventions as they relate to human enhancement. Both panel and exhibition will approach these topics with an emphasis on their social implications, exploring in particular issues relating to sexual reproduction, fertility and sexual technologies – simultaneously raising awareness of sexual politics and the medicalization of the body.

The news item goes on to briefly describe the panelists.

Xenotransplantation—organs for transplantation in human patients—it’s a business and a science

The last time (June 18, 2018 post) I mentioned xenotransplantation (transplanting organs from one species into another species; see more here), it was in the context of an art/sci (or sciart) event coming to Vancouver (Canada).,

Patricia Piccinini’s Curious Imaginings Courtesy: Vancouver Biennale [downloaded from]

The latest edition of the Vancouver Biennale was featured in a June 6, 2018 news item on the Daily Hive (Vancouver),

Melbourne artist Patricia Piccinini’s Curious Imaginings is expected to be one of the most talked about installations of the exhibit. Her style of “oddly captivating, somewhat grotesque, human-animal hybrid creature” is meant to be shocking and thought-provoking.

Piccinini’s interactive [emphasis mine] experience will “challenge us to explore the social impacts of emerging biotechnology and our ethical limits in an age where genetic engineering and digital technologies are already pushing the boundaries of humanity.”

Piccinini’s work will be displayed in the 105-year-old Patricia Hotel in Vancouver’s Strathcona neighbourhood. The 90-day ticketed exhibition [emphasis mine] is scheduled to open this September [2018].

(The show opens on Sept. 14, 2018.)

At the time, I had yet to stumble across Ingfei Chen’s thoughtful dive into the topic in her May 9, 2018 article for,

In the United States, the clock is ticking for more than 114,700 adults and children waiting for a donated kidney or other lifesaving organ, and each day, nearly 20 of them die. Researchers are devising a new way to grow human organs inside other animals, but the method raises potentially thorny ethical issues. Other conceivable futuristic techniques sound like dystopian science fiction. As we envision an era of regenerative medicine decades from now, how far is society willing to go to solve the organ shortage crisis?

I found myself pondering this question after a discussion about the promises of stem cell technologies veered from the intriguing into the bizarre. I was interviewing bioengineer Zev Gartner, co-director and research coordinator of the Center for Cellular Construction at the University of California, San Francisco, about so-called organoids, tiny clumps of organlike tissue that can self-assemble from human stem cells in a Petri dish. These tissue bits are lending new insights into how our organs form and diseases take root. Some researchers even hope they can nurture organoids into full-size human kidneys, pancreases, and other organs for transplantation.

Certain organoid experiments have recently set off alarm bells, but when I asked Gartner about it, his radar for moral concerns was focused elsewhere. For him, the “really, really thought-provoking” scenarios involve other emerging stem cell–based techniques for engineering replacement organs for people, he told me. “Like blastocyst complementation,” he said.

Never heard of it? Neither had I. Turns out it’s a powerful new genetic engineering trick that researchers hope to use for growing human organs inside pigs or sheep—organs that could be genetically personalized for transplant patients, in theory avoiding immune-system rejection problems. The science still has many years to go, but if it pans out, it could be one solution to the organ shortage crisis. However, the prospect of creating hybrid animals with human parts and killing them to harvest organs has already raised a slew of ethical questions. In 2015, the National Institutes of Health placed a moratorium on federal funding of this nascent research area while it evaluated and discussed the issues.

As Gartner sees it, the debate over blastocyst complementation research—work that he finds promising—is just one of many conversations that society needs to have about the ethical and social costs and benefits of future technologies for making lifesaving transplant organs. “There’s all these weird ways that we could go about doing this,” he said, with a spectrum of imaginable approaches that includes organoids, interspecies organ farming, and building organs from scratch using 3D bioprinters. But even if it turns out we can produce human organs in these novel ways, the bigger issue, in each technological instance, may be whether we should.

Gartner crystallized things with a downright creepy example: “We know that the best bioreactor for tissues and organs for humans are human beings,” he said. Hypothetically, “the best way to get you a new heart would be to clone you, grow up a copy of yourself, and take the heart out.” [emphasis mine] Scientists could probably produce a cloned person with the technologies we already have, if money and ethics were of no concern. “But we don’t want to go there, right?” he added in the next breath. “The ethics involved in doing it are not compatible with who we want to be as a society.”

This sounds like Gartner may have been reading some science fiction, specifically, Lois McMaster Bujold and her Barrayar series where she often explored the ethics and possibilities of bioengineering. At this point, some of her work seems eerily prescient.

As for Chen’s article, I strongly encourage you to read it in its entirety if you have the time.

Medicine, healing, and big money

At about the same time, there was a May 31, 2018 news item on offering a perspective from some of the leaders in the science and the business (Note: Links have been removed),

Over the past few years, researchers led by George Church have made important strides toward engineering the genomes of pigs to make their cells compatible with the human body. So many think that it’s possible that, with the help of CRISPR technology, a healthy heart for a patient in desperate need might one day come from a pig.

“It’s relatively feasible to change one gene in a pig, but to change many dozens—which is quite clear is the minimum here—benefits from CRISPR,” an acronym for clustered regularly interspaced short palindromic repeats, said Church, the Robert Winthrop Professor of Genetics at Harvard Medical School (HMS) and a core faculty member of Harvard’s Wyss Institute for Biologically Inspired Engineering. Xenotransplantation is “one of few” big challenges (along with gene drives and de-extinction, he said) “that really requires the ‘oomph’ of CRISPR.”

To facilitate the development of safe and effective cells, tissues, and organs for future medical transplantation into human patients, Harvard’s Office of Technology Development has granted a technology license to the Cambridge biotech startup eGenesis.

Co-founded by Church and former HMS doctoral student Luhan Yang in 2015, eGenesis announced last year that it had raised $38 million to advance its research and development work. At least eight former members of the Church lab—interns, doctoral students, postdocs, and visiting researchers—have continued their scientific careers as employees there.

“The Church Lab is well known for its relentless pursuit of scientific achievements so ambitious they seem improbable—and, indeed, [for] its track record of success,” said Isaac Kohlberg, Harvard’s chief technology development officer and senior associate provost. “George deserves recognition too for his ability to inspire passion and cultivate a strong entrepreneurial drive among his talented research team.”

The license from Harvard OTD covers a powerful set of genome-engineering technologies developed at HMS and the Wyss Institute, including access to foundational intellectual property relating to the Church Lab’s 2012 breakthrough use of CRISPR, led by Yang and Prashant Mali, to edit the genome of human cells. Subsequent innovations that enabled efficient and accurate editing of numerous genes simultaneously are also included. The license is exclusive to eGenesis but limited to the field of xenotransplantation.

A May 30, 2018 Harvard University news release by Caroline Petty, which originated the news item, explores some of the issues associated with incubating humans organs in other species,

The prospect of using living, nonhuman organs, and concerns over the infectiousness of pathogens either present in the tissues or possibly formed in combination with human genetic material, have prompted the Food and Drug Administration to issue detailed guidance on xenotransplantation research and development since the mid-1990s. In pigs, a primary concern has been that porcine endogenous retroviruses (PERVs), strands of potentially pathogenic DNA in the animals’ genomes, might infect human patients and eventually cause disease. [emphases mine]

That’s where the Church lab’s CRISPR expertise has enabled significant advances. In 2015, the lab published important results in the journal Science, successfully demonstrating the use of genome engineering to eliminate all 62 PERVs in porcine cells. Science later called it “the most widespread CRISPR editing feat to date.”

In 2017, with collaborators at Harvard, other universities, and eGenesis, Church and Yang went further. Publishing again in Science, they first confirmed earlier researchers’ fears: Porcine cells can, in fact, transmit PERVs into human cells, and those human cells can pass them on to other, unexposed human cells. (It is still unknown under what circumstances those PERVs might cause disease.) In the same paper, they corrected the problem, announcing the embryogenesis and birth of 37 PERV-free pigs. [Note: My July 17, 2018 post features research which suggests CRISPR-Cas9 gene editing may cause greater genetic damage than had been thought.]

“Taken together, those innovations were stunning,” said Vivian Berlin, director of business development in OTD, who manages the commercialization strategy for much of Harvard’s intellectual property in the life sciences. “That was the foundation they needed, to convince both the scientific community and the investment community that xenotransplantation might become a reality.”

“After hundreds of tests, this was a critical milestone for eGenesis — and the entire field — and represented a key step toward safe organ transplantation from pigs,” said Julie Sunderland, interim CEO of eGenesis. “Building on this study, we hope to continue to advance the science and potential of making xenotransplantation a safe and routine medical procedure.”

Genetic engineering may undercut human diseases, but also could help restore extinct species, researcher says. [Shades of the Jurassic Park movies!]

It’s not, however, the end of the story: An immunological challenge remains, which eGenesis will need to address. The potential for a patient’s body to outright reject transplanted tissue has stymied many previous attempts at xenotransplantation. Church said numerous genetic changes must be achieved to make porcine organs fully compatible with human patients. Among these are edits to several immune functions, coagulation functions, complements, and sugars, as well as the PERVs.

“Trying the straight transplant failed almost immediately, within hours, because there’s a huge mismatch in the carbohydrates on the surface of the cells, in particular alpha-1-3-galactose, and so that was a showstopper,” Church explained. “When you delete that gene, which you can do with conventional methods, you still get pretty fast rejection, because there are a lot of other aspects that are incompatible. You have to take care of each of them, and not all of them are just about removing things — some of them you have to humanize. There’s a great deal of subtlety involved so that you get normal pig embryogenesis but not rejection.

“Putting it all together into one package is challenging,” he concluded.

In short, it’s the next big challenge for CRISPR.

Not unexpectedly, there is no mention of the CRISPR patent fight between Harvard/MIT’s (Massachusetts Institute of Technology) Broad Institute and the University of California at Berkeley (UC Berkeley). My March 15, 2017 posting featured an outcome where the Broad Institute won the first round of the fight. As I recall, it was a decision based on the principles associated with King Solomon, i.e., the US Patent Office, divided the baby and UCBerkeley got the less important part of the baby. As you might expect the decision has been appealed. In an April 30, 2018 piece, Scientific American reprinted an article about the latest round in the fight written by Sharon Begley for STAT (Note: Links have been removed),

All You Need to Know for Round 2 of the CRISPR Patent Fight

It’s baaaaack, that reputation-shredding, stock-moving fight to the death over key CRISPR patents. On Monday morning in Washington, D.C., the U.S. Court of Appeals for the Federal Circuit will hear oral arguments in University of California v. Broad Institute. Questions?

How did we get here? The patent office ruled in February 2017 that the Broad’s 2014 CRISPR patent on using CRISPR-Cas9 to edit genomes, based on discoveries by Feng Zhang, did not “interfere” with a patent application by UC based on the work of UC Berkeley’s Jennifer Doudna. In plain English, that meant the Broad’s patent, on using CRISPR-Cas9 to edit genomes in eukaryotic cells (all animals and plants, but not bacteria), was different from UC’s, which described Doudna’s experiments using CRISPR-Cas9 to edit DNA in a test tube—and it was therefore valid. The Patent Trial and Appeal Board concluded that when Zhang got CRISPR-Cas9 to work in human and mouse cells in 2012, it was not an obvious extension of Doudna’s earlier research, and that he had no “reasonable expectation of success.” UC appealed, and here we are.

For anyone who may not realize what the stakes are for these institutions, Linda Williams in a March 16, 1999 article for the LA Times had this to say about universities, patents, and money,

The University of Florida made about $2 million last year in royalties on a patent for Gatorade Thirst Quencher, a sports drink that generates some $500 million to $600 million a year in revenue for Quaker Oats Co.

The payments place the university among the top five in the nation in income from patent royalties.

Oh, but if some people on the Gainesville, Fla., campus could just turn back the clock. “If we had done Gatorade right, we would be getting $5 or $6 million (a year),” laments Donald Price, director of the university’s office of corporate programs. “It is a classic example of how not to handle a patent idea,” he added.

Gatorade was developed in 1965 when many universities were ill equipped to judge the commercial potential of ideas emerging from their research labs. Officials blew the university’s chance to control the Gatorade royalties when they declined to develop a professor’s idea.

The Gatorade story does not stop there and, even though it’s almost 20 years old, this article stands the test of time. I strongly encourage you to read it if the business end of patents and academia interest you or if you would like to develop more insight into the Broad Institute/UC Berkeley situation.

Getting back to the science, there is that pesky matter of diseases crossing over from one species to another. While, Harvard and eGenesis claim a victory in this area, it seems more work needs to be done.

Infections from pigs

An August 29, 2018 University of Alabama at Birmingham news release (also on EurekAlert) by Jeff Hansen, describes the latest chapter in the quest to provide more organs for transplantion,

A shortage of organs for transplantation — including kidneys and hearts — means that many patients die while still on waiting lists. So, research at the University of Alabama at Birmingham and other sites has turned to pig organs as an alternative. [emphasis mine]

Using gene-editing, researchers have modified such organs to prevent rejection, and research with primates shows the modified pig organs are well-tolerated.

An added step is needed to ensure the safety of these inter-species transplants — sensitive, quantitative assays for viruses and other infectious microorganisms in donor pigs that potentially could gain access to humans during transplantation.

The U.S. Food and Drug Administration requires such testing, prior to implantation, of tissues used for xenotransplantation from animals to humans. It is possible — though very unlikely — that an infectious agent in transplanted tissues could become an emerging infectious disease in humans.

In a paper published in Xenotransplantation, Mark Prichard, Ph.D., and colleagues at UAB have described the development and testing of 30 quantitative assays for pig infectious agents. These assays had sensitivities similar to clinical lab assays for viral loads in human patients. After validation, the UAB team also used the assays on nine sows and 22 piglets delivered from the sows through caesarian section.

“Going forward, ensuring the safety of these organs is of paramount importance,” Prichard said. “The use of highly sensitive techniques to detect potential pathogens will help to minimize adverse events in xenotransplantation.”

“The assays hold promise as part of the screening program to identify suitable donor animals, validate and release transplantable organs for research purposes, and monitor transplant recipients,” said Prichard, a professor in the UAB Department of Pediatrics and director of the Department of Pediatrics Molecular Diagnostics Laboratory.

The UAB researchers developed quantitative polymerase chain reaction, or qPCR, assays for 28 viruses sometimes found in pigs and two groups of mycoplasmas. They established reproducibility, sensitivity, specificity and lower limit of detection for each assay. All but three showed features of good quantitative assays, and the lower limit of detection values ranged between one and 16 copies of the viral or bacterial genetic material.

Also, the pig virus assays did not give false positives for some closely related human viruses.

As a start to understanding the infectious disease load in normal healthy animals and ensuring the safety of pig tissues used in xenotransplantation research, the researchers then screened blood, nasal swab and stool specimens from nine adult sows and 22 of their piglets delivered by caesarian section.

Mycoplasma species and two distinct herpesviruses were the most commonly detected microorganisms. Yet 14 piglets that were delivered from three sows infected with either or both herpesviruses were not infected with the herpesviruses, showing that transmission of these viruses from sow to the caesarian-delivery piglet was inefficient.

Prichard says the assays promise to enhance the safety of pig tissues for xenotransplantation, and they will also aid evaluation of human specimens after xenotransplantation.

The UAB researchers say they subsequently have evaluated more than 300 additional specimens, and that resulted in the detection of most of the targets. “The detection of these targets in pig specimens provides reassurance that the analytical methods are functioning as designed,” said Prichard, “and there is no a priori reason some targets might be more difficult to detect than others with the methods described here.”

As is my custom, here’s a link to and a citation for the paper,

Xenotransplantation panel for the detection of infectious agents in pigs by Caroll B. Hartline, Ra’Shun L. Conner, Scott H. James, Jennifer Potter, Edward Gray, Jose Estrada, Mathew Tector, A. Joseph Tector, Mark N. Prichard. Xenotransplantaion Volume 25, Issue 4 July/August 2018 e12427 DOI: First published: 18 August 2018

This paper is open access.

All this leads to questions about chimeras. If a pig is incubating organs with human cells it’s a chimera but then means the human receiving the organ becomes a chimera too. (For an example, see my Dec. 22, 2013 posting where there’s mention of a woman who received a trachea from a pig. Scroll down about 30% of the way.)

What is it to be human?

A question much beloved of philosophers and others, the question seems particularly timely with xenotransplantion and other developments such neuroprosthetics (cyborgs) and neuromorphic computing (brainlike computing).

As I’ve noted before, although not recently, popular culture offers a discourse on these issues. Take a look at the superhero movies and the way in which enhanced humans and aliens are presented. For example, X-Men comics and movies present mutants (humans with enhanced abilities) as despised and rejected. Video games (not really my thing but there is the Deus Ex series which has as its hero, a cyborg also offer insight into these issues.

Other than popular culture and in the ‘bleeding edge’ arts community, I can’t recall any public discussion on these matters arising from the extraordinary set of technologies which are being deployed or prepared for deployment in the foreseeable future.

(If you’re in Vancouver (Canada) from September 14 – December 15, 2018, you may want to check out Piccinini’s work. Also, there’s ” NCSU [North Carolina State University] Libraries, NC State’s Genetic Engineering and Society (GES) Center, and the Gregg Museum of Art & Design have issued a public call for art for the upcoming exhibition Art’s Work in the Age of Biotechnology: Shaping our Genetic Futures.” from my Sept. 6, 2018 posting. Deadline: Oct. 1, 2018.)

At a guess, there will be pushback from people who have no interest in debating what it is to be human as they already know, and will find these developments, when they learn about them, to be horrifying and unnatural.