Tag Archives: medicine

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Achieving longevity

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moai_profileThere always seems to be some intriguing news on progress in extending lifespans, or achieving what Aubrey De Grey calls engineered negligible senescence. From Physorg we have news that a compound called rapamycin, first discovered on Easter Island, can increase the lifespans of laboratory mice:

The University of Texas Health Science Center at San Antonio and two collaborating centers reported that the Easter Island compound – called “rapamycin” after the island’s Polynesian name, Rapa Nui – extended the expected lifespan of middle-aged mice by 28 percent to 38 percent. In human terms, this would be greater than the predicted increase in extra years of life if cancer and heart disease were both cured and prevented.

Protein folding in certain species of bats has been found to lead to an increase in their lifespans:

Asish and colleagues made their discovery by extracting proteins from the livers of two long-lived bat species (Tadarida brasiliensis and Myotis velifer) and young adult mice and exposed them to chemicals known to cause protein misfolding. After examining the proteins, the scientists found that the bat proteins exhibited less damage than those of the mice, indicating that bats have a mechanism for maintaining proper structure under extreme stress.

And finally the curious case of Brooke Greenberg: who is the size of an infant, with the mental capacity of a toddler, but turned 16 in January:

In a recent paper for the journal “Mechanisms of Ageing and Development,” Walker and his co-authors, who include Pakula and All Children’s Hospital (St. Petersburg, Fla.) geneticist Maxine Sutcliffe chronicled a baffling range of inconsistencies in Brooke’s aging process. She still has baby teeth at 16, for instance. And her bone age is estimated to be more like 10 years old.

“There’ve been very minimal changes in Brooke’s brain,” Walker said. “Various parts of her body, rather than all being at the same stage, seem to be disconnected.”

A substantial increase in human lifespans would be a huge, world-changing, medical and technological achievement, but could well lead to many social problems. An excellent exploration of the effects of longevity is Bruce Sterling‘s sublime Holy Fire.

[from Physorg and abcnews][image from anoldent on flickr]

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Artificial nerve cell breakthrough

line_curve_buildingResearchers at Karolinska Institutet and Linköping University in Sweden have made one more step towards artificial nerve cells with the creation of an artificial nerve cell that can communicate with natural nerve cells using neurotransmitters:

Scientists have now used an electrically conducting plastic to create a new type of “delivery electrode” that instead releases the neurotransmitters that brain cells use to communicate naturally. The advantage of this is that only neighbouring cells that have receptors for the specific neurotransmitter, and that are thus sensitive to this substance, will be activated.

The scientists intend to continue with the development of a small unit that can be implanted into the body. It will be possible to program the unit such that the release of neurotransmitters takes place as often or as seldom as required in order to treat the individual patient.

As ever the initial applications are intended to be towards treating diseases like Parkinson’s disease or epilepsy. Progress on these fronts would be wonderful. But what further applications will become possible when this product matures?

[from Physorg][image from takanawho on flickr]

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The regeneration game

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salamanderExciting results from the world of biology, with implications for human medicine: researchers looking at the limb regeneration process in salamanders have discovered that it works in a different way to what they thought previously. [image by jurvetson]

Rather than having their cellular clocks fully reset and reverting to an embryonic state, cells in the salamanders’ stumps became slightly less mature versions of the cells they’d been before. The findings could inspire research into human tissue regeneration.

“The cells don’t have to step as far back as we thought they had to, in order to regenerate a complicated thing like a limb,” said study co-author Elly Tanaka, a Max Planck Institute cell biologist. “There’s a higher chance that human or mammalian cells can be induced into doing the same thing.”

[…]

They found that salamander regeneration begins when a clump of cells called a blastema forms at the tip of a lost limb. From the blastema come skin, muscle, bone, blood vessels and neurons, ultimately growing into a limb virtually identical to the old one.

Researchers, many of whom hoped their findings could someday be used to heal people, hypothesized that as cells joined blastemas, they “de-differentiated” and became pluripotent — able to become any type of tissue. Embryonic stem cells are also pluripotent, as are cells that have been genetically reprogrammed through a process called induced pluripotency.

Such cells have raised hopes of replacing lost or diseased tissue. They’re also difficult to control and prone to turning cancerous. These problems may well be the inevitable growing pains of early-stage research, but could also represent more fundamental limits in cellular plasticity.

If Tanaka’s right that blastema cells don’t become pluripotent, then the findings raise another possibility — not just for salamanders, but for people. Rather than pushing cellular limits, perhaps researchers could work within nature’s parameters.

Another step towards transhuman immortality, perhaps? It’s fun seeing such science fictional subjects in ‘regular’ news venues, if only to watch journalists asking the sort of questions science fiction has always hinged on – like Khaled Diab at The Guardian, for example, trying to imagine what the world would be like if Aubrey De Grey is right about the immortality singularity:

Should people’s lives be extended indefinitely? If not, should society or the individual choose when to pull the plug? Should a 250-year-old physical teen be treated as an adult and served alcohol or not? Would society take long-term threats, such as the environment, more seriously because people will actually live to see the consequences? Does living so long rob future generations of their right to life? Would you like to live in a society without death?

I figure that, if it happens, we’ll work out a way to cope during the journey – much like Jamais Cascio suggests we’ll cope fine with intelligence augmentation, because it’s an iterative process rather than a momentary leap of change.

Of course, De Grey has already secured himself one form of immortality – the only form of it in which I’d be interested, anyway. I’m sympathetic to the transhumanist project, but the thought of living forever just doesn’t appeal to me. I’ve always theorised that without the ticking clock of mortality we’d have very little to motivate us to create anything new or unique; you struggle to produce a legacy to fill the void of your leaving, if you will. Of course, my attitudes may change as I get older… but even so, if offered the choice right now I’d settle for a standard lifespan minus the gradual decline into senescence and frailty at the end. Death doesn’t scare me, but dying slowly sure does.

Should people’s lives be extended indefinitely? If not, should society or the individual choose when to pull the plug? Should a 250-year-old physical teen be treated as an adult and served alcohol or not? Would society take long-term threats, such as the environment, more seriously because people will actually live to see the consequences? Does living so long rob future generations of their right to life? Would you like to live in a society without death?

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Fiction

NEW FICTION: HOMEOSTASIS by Carlos Hernadez

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It’s the first of July – time for your monthly dose of Futurismic fiction! This time, we’ve got a story that probably comes closer to the sort of thing we try to achieve with our blogging output than anything we’ve yet published. “Homeostasis” is a plainly-told story about real people adapting to a plausible piece of tomorrow’s life-saving medical technology; Carlos Hernandez understands that science fiction can pitch hard and still have a heart. Enjoy!

Homeostasis

by Carlos Hernandez

Eight seconds of footage, from a security camera so old it surrounds every object in the picture with rainbows. Man at a gas station robbing the attendant. Pantyhose flattening his nose. Waving a knife like a snakecharmer’s pungi.

Customer walks in. Good-looking guy, California hair, white as a country club. Has no idea; walks in texting. The robber runs over and slams the knife through the top of his head. In to the hilt.

On 4chan’s boards, someone posts an animated gif that infinitely loops the last two seconds. The word “pwnd” flashes at the end. Dozens of people respond with “lulz.” Continue reading NEW FICTION: HOMEOSTASIS by Carlos Hernadez

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Enzyme linked to longevity

enzyme_WWP-1Researchers have discovered a key enzyme – WWP-1 – that forms part of the process by which caloric restriction leads to longer lifespans in roundworms:

“The only other known factor regulating longevity in response to diet restriction operates at the very end of the signaling cascade,” said Howard Hughes Medical Investigator and senior author Andrew Dillin, Ph.D., an associate professor in the Molecular and Cell Biology Laboratory. “These two enzymes are further up the ladder, bringing us closer to the receptor that receives the signal for throwing the switch to promote a healthy lifespan.”

Identifying the receptor may allow researchers to design drugs that mimic the signal and could lead to new treatments for age-related diseases. This could enable us to reap the health benefits of calorie restriction without adhering to extreme diets in which the satisfying feel of a full stomach is strictly off limits.

The kind of medicine described is definitely near the top of my plausible future technologies that may emerge in my lifetime.

[at Physorg][image from Physorg]