This year's BIL unconference will be held on March 3rd, on the Queen Mary in Long Beach, California.

BIL is an ad-hoc conference for people changing the world in big ways. It's a place for passionate people to come together to energize, brainstorm, and take action. ... Most of you have heard of TED or watched the talks online, but do you know about BIL, the quirky, populist, unconference taking place nearby? Open to the public and fully participant powered, BIL features a wild mix of technologists, scientists, artists, hackers, and those with a passion for community awareness.

Amongst those scheduling themselves to speak are Aubrey de Grey of the SENS Foundation and Max More of Alcor:

De Grey's research focuses on whether regenerative medicine can thwart the aging process. He works on the development of what he calls "Strategies for Engineered Negligible Senescence" (SENS), a tissue-repair strategy intended to rejuvenate the human body and allow an indefinite lifespan. To this end, he has identified seven types of molecular and cellular damage caused by essential metabolic processes. SENS is a proposed panel of therapies designed to repair this damage.

...

Max More is an internationally acclaimed strategic philosopher widely recognized for his thinking on the philosophical and cultural implications of emerging technologies. ... At the start of 2011, he became President and CEO of the Alcor Life Extension Foundation, the world's leading cryonics organization. ... Max will give a fresh perspective on cryonics as a bridge to an indefinitely extended life.

You'll find some other familiar faces in the list of participants, some of whom are also quite active in the longevity science advocacy community.

The visible future is by any sensible measure nothing less than science fiction. Any given snapshot of that future is made up of countless trillions of ageless humans, sophisticated machine intelligences, and yet to be categorized hybrids of the two, spread throughout the solar system in palatial standards of living, and beginning to drift beyond to the nearby stars - a vast thistledown of intelligence and culture, a million times greater and more diverse than today's world, just beginning its explosion into the winds. These are the Inheritors, to borrow a term from an obscure work of science fiction.

The question for today is this: to what degree are we obligated by the Inheritors? They are yet to exist, but we know that we can bring them into being, and indeed seem to be headed in that direction: there is nothing especially controversial about a future cosmopolitan solar system, or the ability to defeat aging given a sufficiently long timescale to work on the necessary biotechnology. These technologies and research programs can be envisaged in some detail, and human ingenuity will achieve all of these goals in the fullness of time. (Though human nature being what it is research on the technologies of the future will be achieved painstakingly and ever so slowly on a shoestring budget, whilst the lion's share of the flow of expenditures in every society go to bread and circuses).

From a utilitarian perspective, one could argue that creating and perpetuating intelligences possessed of free will, freedom, and opportunity is the highest aspiration, the greatest end goal for human action - turning clay into sentience, as it were. Speeding any step towards the technologies necessary for the existence of the Inheritors (enhanced longevity, control of disease, strong artificial intelligence, low cost orbital lift systems, and so forth) will ultimately bring a benefit that is measured in millions of lives - even in increments of a day here, a day there. This is time lived in aggregate: deaths prevented, additional person-days lived well per day, days of suffering eliminated, and so forth.

Arguments for speed in longevity research based on saving lives in the future - bringing the advent of rejuvenation biotechnology one day closer will save at least 100,000 lives over the span of its introduction to the clinics, for example - are a narrow slice of broader arguments for speeding the development of the other foundation technologies of the Inheritors.

But are we obligated to the future? This seems to me to be an all or nothing question: are we obligated in the sense that we agree with Aubrey de Grey when he says that the ethical thing to do is to work hard on longevity technologies because it will give our descendants the choice of whether or not to use them - rather than lazing around and bequeathing them the same lack of choice that our ancestors had? If so, then shouldn't we also be obligated to the Inheritors as a result of much the same line of reasoning? And indeed, look beyond the Inheritors. The future of humanity, unless abruptly and unexpectedly halted, is to turn our future light cone into sentient matter. On that scale of time, space, culture, and intelligence the Inheritors are a tiny primordial instant. Are we obligated to the extent of the future that we cannot well envisage, only seeing that it must be vast beyond easy comprehension?

These are things to think about when you roll out of bed to face another day, and when you make the choice on your own plans and strategies for the years ahead.

The bottom line is that obligation is a choice. It is choice and freedom to choose that separates obligation from slavery: the difference between working because you feel that you should and working because you are compelled. The Inheritors, being nothing more than a plausible and probably inevitable vision at this point, cannot compel the present. To help speed the day of their existence, and to work on rejuvenation biotechnology and cryonics for a shot at seeing that era with our own eyes - these are choices. Weighty choices indeed, but freely made.

FIGHT AGING! NEWSLETTER
February 20th 2012

The Fight Aging! Newsletter is a weekly email containing news, opinions, and happenings for people interested in aging science and engineered longevity: making use of diet, lifestyle choices, technology, and proven medical advances to live healthy, longer lives. This newsletter is published under the Creative Commons Attribution 3.0 license. In short, this means that you are encouraged to republish and rewrite it in any way you see fit, the only requirements being that you provide attribution and a link to Fight Aging!

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CONTENT

- SENS5 Video: Questions of Resource Allocation
- Eight Years of Fight Aging!
- A Few Items of Tissue Engineering News
- The Aging of Stem Cells
- On End of Life Timing for Cryonics
- Discussion
- Latest Headlines from Fight Aging!

SENS5 VIDEO: QUESTIONS OF RESOURCE ALLOCATION

Resources in research and medical development seems to be the unifying topic here at Fight Aging! for the past week or so. It is interesting to these accidental thematic collections of content come and go in passing, all without any deliberate intent; a reminder that we take small samples from a much broader, many-threaded conversation of millions of people, one that spans all media and has its tides and fashions at every timescale. So continuing the theme, here is a newly processed and posted video from the SENS5 conference:

http://www.fightaging.org/archives/2012/02/sens5-video-questions-of-resource-allocation.php

EIGHT YEARS OF FIGHT AGING!

Tempus fugit:

http://www.fightaging.org/archives/2012/02/eight-years-of-fight-aging.php

"The end of last month marked the close of the eighth year of Fight Aging!, and here we are in year nine of this bullheaded endeavor - the idea that the good can eventually drive out the bad in the online world of information on aging, longevity, and what best to do about the degenerations that await us all. Optimism shines eternal, I know, but as the science of human rejuvenation becomes ever closer to reality, the shysters and the marketeers of the 'anti-aging' industry must eventually go the way of the real snake oil salesmen of old, travelling cart and all. Along with them must go the apologists for aging, the people who would force death upon everyone, and the other malignant naysayers.

"Eight years was more than long enough for me to traverse that interesting section of life during which one first starts to notice the signs of decay - the things that don't work quite so well anymore, the initial small signs of what will be a lot worse later on. It makes it a good deal harder to avoid dwelling upon just how lousy the human condition is, all things considered. But that's all relative: I can tell you that the human condition is a raw deal because I can look ahead and see just how much of an improvement is possible through well-envisaged future technologies - not that there's anything special about being able to do that, but in this era we can be a lot more specific than our visionary ancestors. We can explain in some detail how we will defeat all disease, eliminate suffering, and of course remove aging as a threat to life and health. No serious, knowledgeable thinker can argue against these goals as possible and plausible, given our present understanding of physics and biology. We are machinery, our malfunctions are only a matter of atoms out of place, and precision control of atoms will be the basis for all of our technologies sooner or later. The world is our oyster in the realm of what is possible, but as always the question is how soon that future will arrive."

A FEW ITEMS OF TISSUE ENGINEERING NEWS

Tissue printing startup Organovo, which the Methuselah Foundation invested in some years back, has received a new round of funding. You'll find that and a couple of other recent items of interest from the tissue engineering field in the following Fight Aging! post:

http://www.fightaging.org/archives/2012/02/a-few-items-of-tissue-engineering-news.php

"Organovo closed a private placement consisting of approximately 6.5 million units of its securities to qualified accredited investors, for total gross proceeds of $6.5 million. 'Organovo's advanced bioprinting platform can replicate essential biology for research, drug discovery and development and, eventually, for therapeutic applications,' stated Keith Murphy, chief executive officer of Organovo. 'We have found success in achieving early revenue through strategic collaborations, and this funding will allow us to extend the reach and uses of 3D bioprinting through growth and innovation in the coming years.'"

THE AGING OF STEM CELLS

Another in the series of posters from the Science for Life Extension Foundation has been translated from the original Russian. This one provides an overview of what is known of the mechanisms and details of aging stem cell populations and their impact on the body:

http://www.fightaging.org/archives/2012/02/a-poster-on-the-aging-of-stem-cells-from-the-science-for-life-extension-foundation.php

ON END OF LIFE TIMING FOR CRYONICS

Cryonics is the low temperature storage of the body after death, to preserve the fine structure of the brain to wait on future technologies that can repair cellular damage and restore these patients to active life. It's far from a sure thing, but it beats the alternative for the many in the community who won't live long enough to benefit from biotechnologies of rejuvenation. One of the hurdles that makes the organization of your own cryopreservation more expensive and uncertain than it has to be is that US law, where most cryonics providers are based, makes end of life determination largely illegal:

http://www.fightaging.org/archives/2012/02/a-practical-approach-to-managing-end-of-life-timing-for-cryopreservation.php

"One of the biggest challenges inherent in organizing your own cryopreservation in the US is that all of the best, most comfortable, and most optimal ways of timing the end of your life are illegal - not just for you, but for everyone who would be involved in helping you. This makes the act of cryopreservation vastly more expensive and prone to delays that will cause extensive damage to the fine structure of the brain, and all of this stems from the interference of state employees, enforcing laws made by other state employees who are both unaccountable and uncaring. Try to do the morally right thing and end up in jail. Thus teams must be on standby for weeks or months for any given patient who is approaching the end of their life, the patient must suffer through to the bitter end, and the time from notice of death to cooled vitrification of the body is inevitably much longer than it might otherwise be.

"This is why the right to self-determination in end of life choices, and the right to contract to help people enact those choices by providing goods and services, is so important for the cryonics community. But it should be important for everyone interested in enhanced human longevity: a government whose employees grant themselves the right to decide the timing of your death is a government that can also reach out to make it very hard to extend your life even if the means are available. And in fact, there is a lot of that already going on in the fact that therapies for aging cannot be approved for use in the US under the present system of regulation. That fact already goes a long way towards suppressing research and development towards that end goal. At root, this all comes back to self-ownership and self-determination: is it your life and your body? From modern government employees, the answer is largely 'no.'"

DISCUSSION

The highlights and headlines from the past week follow below. Remember - if you like this newsletter, the chances are that your friends will find it useful too. Forward it on, or post a copy to your favorite online communities. Encourage the people you know to pitch in and make a difference to the future of health and longevity!

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LATEST HEADLINES FROM FIGHT AGING!

INFLAMMATION AND THE STIFFNESS OF BLOOD VESSELS
Friday, February 17, 2012
http://www.fightaging.org/archives/2012/02/inflammation-and-the-stiffness-of-blood-vessels.php
One of the ways in which major blood vessels decline in function with aging is that they lose their elasticity. The state of chronic inflammation that grows with aging contributes to this, as noted in this open access paper (in PDF format). This is probably connected to the fact that exercise helps improve the elasticity of arteries, given that exercise is shown to impact levels of inflammation: "Increased arterial stiffness is an independent predictor of cardiovascular disease independent from blood pressure. Recent studies have shed new light on the importance of inflammation on the pathogenesis of arterial stiffness. Arterial stiffness is associated with the increased activity of angiotensin II, which results in increased NADPH oxidase activity, reduced NO bioavailability and increased production of reactive oxygen species. Angiotensin II signaling activates matrix metalloproteinases (MMPs) which degrade TGFβ precursors to produce active TGFβ, which then results in increased arterial fibrosis. ... There is also ample clinical evidence that demonstrates the association of inflammation with increased arterial stiffness. Recent studies have shown that reductions in inflammation can reduce arterial stiffness. In patients with rheumatoid arthritis, increased aortic pulse wave velocity in patients was significantly reduced by anti tumor necrosis factor-α therapy. ... Thus, there is rationale for targeting specific inflammatory pathways involved in arterial stiffness in the development of future drugs. Understanding the role of inflammation in the pathogenesis of arterial stiffness is important to understanding the complex puzzle that is the pathophysiology of arterial stiffening and may be important for future development of novel treatments."

2ND INTERNATIONAL CONFERENCE ON AGING AND LONGEVITY
Friday, February 17, 2012
http://www.fightaging.org/archives/2012/02/2nd-international-conference-on-aging-and-longevity.php
From Maria Konovalenko: "I am proud to announce that Science for Life Extension Foundation is one of the organizers of the 2nd international Genetics of Aging and Longevity conference. It is going to be an amazing and actually unprecedented conference focused on genetic mechanisms of aging and longevity. Check out the list of our invited speakers. I can't wait to hear the prominent researchers sharing their experience in making model animals live longer. By the way, we are proud to have all the longevity-record braking researchers, who extended the lifespan of yeast, nematodes, fruit flies and mice. You can't miss this meeting. I encourage you to go ahead and register. It's the end of April, beautiful spring in Moscow. For those who have never been here before, here's your chance to kill two birds with one stone - learn a lot about aging and discover one of the most beautiful and dynamic cities in the world."

SIMPLE MEASURES OF ROBUSTNESS PREDICT FUTURE HEALTH
Thursday, February 16, 2012
http://www.fightaging.org/archives/2012/02/simple-measures-of-robustness-predict-future-health.php
I would take this as an indicator that simple, ongoing maintenance of fitness and avoidance of a sedentary lifestyle pays off: "Simple tests such as walking speed and hand grip strength may help doctors determine how likely it is a middle-aged person will develop dementia or stroke. ... More than 2,400 men and women with an average age of 62 underwent tests for walking speed, hand grip strength and cognitive function. Brain scans were also performed. During the follow-up period of up to 11 years, 34 people developed dementia and 70 people had a stroke. The study found people with a slower walking speed in middle age were one-and-a-half times more likely to develop dementia compared to people with faster walking speed. Stronger hand grip strength was associated with a 42 percent lower risk of stroke or transient ischemic attack (TIA) in people over age 65 compared to those with weaker hand grip strength. This was not the case, however, for people in the study under age 65. ... Researchers also found that slower walking speed was associated with lower total cerebral brain volume and poorer performance on memory, language and decision-making tests. Stronger hand grip strength was associated with larger total cerebral brain volume as well as better performance on cognitive tests asking people to identify similarities among objects." We might theorize that this is related to exercise and blood flow in the brain, and related effects on the heath of blood vessels in the brain.

SHORTER TELOMERES CORRELATE WITH A HIGHER RISK OF HEART ATTACK AND EARLY DEATH
Thursday, February 16, 2012
http://www.fightaging.org/archives/2012/02/shorter-telomeres-correlate-with-a-higher-risk-of-heart-attack-and-early-death.php
Average telomere length in at least some tissues makes a good marker for general health, but the progressive shortening of telomeres may or may not be a root cause of aging. Telomere length results from a dynamic system of lengthening and shortening processes, which seems more likely to be a reflection of underlying function and dysfunction: "In an ongoing study of almost 20,000 Danes, a team of researchers [have] isolated each individual's DNA to analyse their specific telomere length - a measurement of cellular aging. ... The risk of heart attack or early death is present whether your telomeres are shortened due to lifestyle or due to high age ... The recent Copenhagen General Population Study involved almost 20,000 people, some of which were followed during almost 19 years, and the conclusion was clear: If the telomere length was short, the risk of heart attack and early death was increased by 50 and 25 per cent, respectively. ... That smoking and obesity increases the risk of heart disease has been known for a while. We have now shown, as has been speculated, that the increased risk is directly related to the shortening of the protective telomeres - so you can say that smoking and obesity ages the body on a cellular level, just as surely as the passing of time. ... one in four Danes has telomeres with such short length that not only will they statistically die before their time, but their risk of heart attack is also increased by almost 50 per cent. Future studies will have to reveal the actual molecular mechanism by which the short telomere length causes heart attacks. Does one cause the other or is the telomere length and the coronary event both indicative of a third - yet unknown - mechanism?" I lean towards the latter hypothesis, that both risk of catastrophic failure in bodily systems and telomere length reflect levels of accumulated damage at the level of cells and macromolecules in the body.

TRACING THE PATHWAY BACK FOR RESVERATROL
Wednesday, February 15, 2012
http://www.fightaging.org/archives/2012/02/tracing-the-pathway-back-for-resveratrol.php
Resveratrol in and of itself is likely not terribly interesting for work on longevity - and certainly not worthy of the hype surrounding it. The same probably goes for sirtuins in general. This, however, is still a good example of work on tracing back the pathways of action of a metabolic change agent: "Research has previously suggested that resveratrol acts through activation of the sirtuin (SIR) gene family. This gene pathway, though controversial, has been implicated in life extension across several species. It has been reported that SIR extends lifespan in much the same way as caloric restriction which itself in turn may activate SIR. It has remained unclear however if resevertrol directly activates SIR or if it acts on SIR indirectly via another intermediary biochemical pathway. The current study successfully answered that question. Using several cell biology techniques the authors were able to demonstrate that resveratrol actually functions to activate SIR indirectly. They showed that resveratrol is really a phosphodiesterase inhibitor (PDE4). They demonstrated that reducing PDE4 allows cyclic AMP (cAMP) levels in the cells to rise. cAMP then increases the activity of AMPK which next increases NAD+ which finally increases SIR. This elegant study then went on to prove that the same life extending benefits of resveratrol could be achieved in rats by administering them the PDE4 inhibitor rolipram. ... inhibiting PDE4 with rolipram reproduces all of the metabolic benefits of resveratrol, including prevention of diet-induced obesity and an increase in mitochondrial function, physical stamina, and glucose tolerance in mice. "

INVESTING IN LONGEVITY SCIENCE
Wednesday, February 15, 2012
http://www.fightaging.org/archives/2012/02/investing-in-longevity-science.php
An excellent article from CNBC looks at some of the few figures in the investment community who support progress towards extended healthy lifespans: "what if 'getting old' wasn't really 'getting old?' What if aging - at least the physical deteriorations that accompany it - was something that could be prevented? It's a lofty idea, but it's one that a new breed of biotech start-ups, scientists, and prominent investors are beginning to tackle. Peter Thiel is one of those investors. ... Back in 2006, Thiel gave Cambridge anti-aging researcher Aubrey de Grey $3.5 million under the auspices of the Methusaleh Foundation, a non-profit headquartered in Springfield, Virgina, that awards scientists who are working on life-extension therapies. 'Probably the most extreme form of inequality is between people who are alive and people who are dead,' Thiel told The New Yorker. In 2010, Thiel and his partners at Founders Fund, a Bay Area venture capital firm, invested $500,000 in Halcyon Molecular, a biotech start-up whose 28-year-old founder has a 'dream to create a world free from cancer and aging.' To understand the fund's investment, you have to appreciate what Founders Fund is - or, more specifically, what it is not. 'These are not guys who care about an extra million dollars,' says Brian Singerman, a partner at Founders Fund along with Thiel. 'These are guys who wanted to do something amazing for the world.' Singerman, an early employee at Google, [came] to Founders Fund after having what he describes as an 'epic six hour epic dinner with Sean Parker.' Equal parts brilliant and idealistic, Singerman is adamant that aging is a problem that can be solved. The fund's portfolio has invested in about 14 health and biotech companies all interested in solving life's ultimate problem: death. ... We have a company that's charged with curing all viral disease, we have a company that's charged with curing several types of cancer. These are not things that are incremental approaches. It's all fine and good to have a drug that extends life by a certain amount of months or makes living with a disease easier. That's not what we're looking for. We are not looking for incremental change. We are looking for absolute cures in anything we do."

MORE EATING, MORE MEMORY LOSS
Tuesday, February 14, 2012
http://www.fightaging.org/archives/2012/02/more-eating-more-memory-loss.php
Another good reason to be practicing calorie restriction: "New research suggests that consuming between 2,100 and 6,000 calories per day may double the risk of memory loss, or mild cognitive impairment (MCI), among people age 70 and older. ... We observed a dose-response pattern which simply means; the higher the amount of calories consumed each day, the higher the risk of MCI. ... The study involved 1,233 people between the ages of 70 and 89 and free of dementia residing in Olmsted County, Minn. Of those, 163 had MCI. Participants reported the amount of calories they ate or drank in a food questionnaire and were divided into three equal groups based on their daily caloric consumption. One-third of the participants consumed between 600 and 1,526 calories per day, one-third between 1,526 and 2,143 and one-third consumed between 2,143 and 6,000 calories per day. The odds of having MCI more than doubled for those in the highest calorie-consuming group compared to those in the lowest calorie-consuming group. The results were the same after adjusting for history of stroke, diabetes, amount of education, and other factors that can affect risk of memory loss. There was no significant difference in risk for the middle group."

TREATING HEART ATTACK DAMAGE WITH STEM CELLS
Tuesday, February 14, 2012
http://www.fightaging.org/archives/2012/02/treating-heart-attack-damage-with-stem-cells.php
A recent trial shows benefits: "treating heart attack patients with an infusion of their own heart-derived cells helps damaged hearts re-grow healthy muscle. Patients who underwent the stem cell procedure demonstrated a significant reduction in the size of the scar left on the heart muscle by a heart attack. Patients also experienced a sizable increase in healthy heart muscle following the experimental stem cell treatments. One year after receiving the stem cell treatment, scar size was reduced from 24 percent to 12 percent of the heart in patients treated with cells (an average drop of about 50 percent). Patients in the control group, who did not receive stem cells, did not experience a reduction in their heart attack scars. ... While the primary goal of our study was to verify safety, we also looked for evidence that the treatment might dissolve scar and regrow lost heart muscle. This has never been accomplished before, despite a decade of cell therapy trials for patients with heart attacks. Now we have done it. The effects are substantial, and surprisingly larger in humans than they were in animal tests. ... In the past, all we could do was to try to minimize heart damage by promptly opening up an occluded artery. Now, this study shows there is a regenerative therapy that may actually reverse the damage caused by a heart attack."

AN APPROACH TO SPURRING REGROWTH OF BLOOD VESSELS
Monday, February 13, 2012
http://www.fightaging.org/archives/2012/02/an-approach-to-spurring-regrowth-of-blood-vessels.php
Researchers are working on many different approaches to spur regrowth of blood vessels in the body. Here is one of them: "researchers have demonstrated a new and more effective method for regrowing blood vessels in the heart and limbs ... The treatment method [could] allow doctors to bypass surgery and instead repair damaged blood vessels simply by injecting a lipid-incased substance into a patient. Once inside the body, the substance stimulates cell growth and spurs the growth of new blood vessels from pre-existing ones. ... Others have tried using growth factors to stimulate vessel growth in clinical trials and have not been successful. We think that a major reason for this is that previous methods assumed that the diseased tissues retained the ability to respond to a growth stimulus. Our method basically delivers extra components that can restore growth factor responsiveness to the tissue of patients with long-standing clinical disease. ... The method combines a growth factor - a substance capable of stimulating cellular growth, proliferation and cellular differentiation, as well as healing wounds - known as fibroblast growth factor 2 (FGF-2) with a lipid-embedded receptor to enhance its activity. A challenge for scientists and engineers, however, has been getting FGF-2 to bind with cell receptors - the very molecules often found on the surface of the cell that receive chemical signals and direct activity in the cell from outside sources. To overcome this, [the new] method embeds the growth factors in synthetic lipid-based nanoparticles containing a coreceptor known as syndecan-4. The nanoparticles containing co-receptors that, when delivered with the growth factor, enable improved cell binding so that the growth factor can direct the targeted cell to divide, proliferate and form new cells for tissue regrowth. The incased substance was injected into rats with hindlimb ischemia and stimulated a complete recovery from the ischemia in just seven days."

BOOSTING REPAIR OF MYELIN SHEATHS IN THE BRAIN
Monday, February 13, 2012
http://www.fightaging.org/archives/2012/02/boosting-repair-of-myelin-sheaths-in-the-brain.php
Researches have been boosting stem cell populations via the method demonstrated here for more than five years, but here they're demonstrating a better and more refined outcome: "myelin [is] a material that forms a protective, insulating cape around the axons of our nerve cells so that they can send signals quickly and efficiently. But myelin, and the specialized cells called oligodendrocytes that make it, become damaged in demyelinating diseases like multiple sclerosis (MS), leaving neurons without their myelin sheaths. As a consequence, the affected neurons can no longer communicate correctly and are prone to damage. ... We've developed a gene therapy to stimulate production of new oligodendrocytes from stem and progenitor cells - both of which can become more specialized cell types - that are resident in the adult central nervous system. In other words, we're using the brain's own progenitor cells as a way to boost repair. ... The therapy uses leukemia inhibitory factor (LIF), a naturally occurring protein that was known to promote the self-renewal of neural stem cells and to reduce immune-cell attacks to myelin in other MS mouse models. ... What hadn't been done before our study was to use gene therapy in the brain to stimulate these cells to remyelinate. ... It was thought that you could use factors to stimulate the division and expansion of the progenitor population, and then add additional factors to direct those progenitors to turn into the mature myelin-forming cells. But in our mouse model, when we give our LIF therapy, it both stimulates the proliferation of the progenitor cells and allows them to differentiate into mature oligodendrocytes."

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Via Maria Konovalenko, here is another attractive poster on the biology of aging from some of the folk behind the Russian Science for Life Extension Foundation. There are more of these documents out there than are translated to English, more is the pity, but the supply of people who can make good technical translations in cutting edge life science from Russian to English (and have both the time and motivation to do so) is limited at the best of times. The image below is low-quality - click through for the full size version.

You might look back in the Fight Aging! archives for a few more of these posters:

• A Regenerative Medicine Roadmap from the Science for Life Extension Foundation
• Biomarkers of Aging and Age-Related Conditions

You'll also find other documents at the Science for Life Extension Foundation website (scroll down for the links) and if you're up for reading the original Russian, you'll find a great deal of similarly interesting material at researcher Alexey Moskalev's blog.

Tissue printing startup Organovo, of the Methuselah Foundation's portfolio of early stage investments, received a new round of funding recently:

Organovo closed a private placement consisting of approximately 6.5 million units of its securities to qualified accredited investors, for total gross proceeds of $6.5 million. "Organovo's advanced bioprinting platform can replicate essential biology for research, drug discovery and development and, eventually, for therapeutic applications," stated Keith Murphy, chief executive officer of Organovo. "We have found success in achieving early revenue through strategic collaborations, and this funding will allow us to extend the reach and uses of 3D bioprinting through growth and innovation in the coming years."

Given that at this stage in their life cycle they are essentially a research equipment manufacturer, that sort of money - while small in terms of medical development in the mainstream - should be enough to get them to the next level. You might recall an h+ Magazine article from a couple of years ago that gives a good overview of what the company aims to achieve:

Dr. Forgacs ultimately foresees fully implantable organs printed from a patient's own cells. "You give us your cells: we grow them, we print them, the structure forms and we are ready to go," he says. "I am pretty sure that full organs will be on the market [one day]." A printed biological heart might not appear exactly like an embryonic heart with a pericardium, two superior atria, and two inferior ventricles. But it will perform the same function: pumping blood throughout the blood vessels.

The second item relates to the preservation of organs for later transplant: this is a big logistical hurdle. A great deal of the processes of present day transplantation and early tissue engineering are completely shaped by our inability to reliably store large, complex tissues for the long term, without damage. The process of decellularization may be a practical way to work around the issue, though it remains to be seen if the economics work out yet: donated organs can be decellularlized, the scaffold stored at low temperature, and then warmed up and repopulated with a patient's cells in a matter of days. Here is a note from ScienceDaily, which leads to an open access research paper that is available in PDF format:

[Researchers] studied various strategies for freeze-drying porcine heart valves. After the cellular material was removed, they freeze-dried the heart valve scaffolds with or without sucrose and hydroxyl ethylene starch, and then compared the stability and elasticity of the freeze-dried scaffolds to assess the effectiveness of these lyoprotectants in preventing degradation of the scaffold. ... Tissue freeze-dried with sucrose alone displayed less porosity compared to tissue freeze-dried with the sucrose/HES mixture, whereas no significant differences in biomechanical properties were observed. Decellularization decreased the elastic modulus of artery tissue. The elastic modulus of freeze-dried tissue without protectants resembled that of decellularized tissue. The elastic modulus values of freeze-dried tissue stabilized by lyoprotectants were greater compared to those of decellularized tissue, but similar to those of native tissue.

Lastly for today, an article on one of the challenges of tissue engineering that people outside the field don't tend to think all that much about, which is that it is exceedingly difficult to convince tissues to form exactly the desired shape, with exactly the right mechanical properties, and with the right cells in the right place in that shape. A lot of researchers are spending a lot of time on determining how to cultivate tissue of the right size and shape; the strategies needed vary greatly by tissue type and other circumstances. In any case, here is an article on tubes:

In another advance for the field, researchers have now demonstrated a strategy to fabricate tubular structures with multiple types of cells as different layers of the tube walls. This method may be widely used in simulation of many tubular tissues and enriches the toolbox for 3D micro/nanofabrication by initially patterning in 2D and transforming it into 3D. ... To demonstrate the capability of their method, the scientists successfully simulated the structure of a human vessel-like structure - the tubular wall has three layers, and in each layer there is one representative type of cells: endothelial cells, smooth muscle cells and fibroblast cells (from inside out). This kind of tubular structure with multiple types of cells can be applied in tissue engineering such as arterial and venous grafts in vivo. And [the] preparation method of stress-induced rolling membrane can be applied to fabricate other self-assembled 3D structures.

You might compare the methodologies in the technology demonstration quoted above with the approach used in growing mouse teeth to get a sense of just how broad the range of necessary techniques is.