Michael Fossel Michael is President of Telocyte

February 1, 2018

Aging and Disease: 1.0 – Aging, Our Purpose, Our Perspective:

Aging is poorly understood, While the process seems obvious, the reality is far more complex than we realize. In this series of blogs I will explain how aging works and how aging results in disease. In passing, I will touch upon why aging occurs and will culminate in an explanation of the most effect single point of intervention, both clinically and financially. We will likewise explore the techniques, costs, and hurdles in taking such intervention into common clinical use in the next few years.

The approach will be magesterial, rather than academic. I do not mean to preclude differences of opinion, but my intent is not to argue. I will explain how aging works, rather than engage in theoretical disputes. Many of the current academic disputes regarding aging are predicated on unexamined assumptions and flawed premises, resulting in flawed conclusions. Rather than argue about the conclusions; I will start from basics, highlight common pitfalls in our assumptions and premises, then proceed to show how aging and age-related diseases occur.

Since this is not and is not intended to be an “Academic” series (capitalization is intentional), I will aim at the educated non-specialist and will usually omit references, in order to make engagement easier for all of us as the series proceeds. If any of you would like references, more than 4,200 academic references are available in my medical textbook on this topic, Cells, Aging, and Human Disease (Oxford University Press, 2004). For those of you with a deep intellectual exploration of this topic, I recommend you read my textbook. Ironically, my academic textboo is still largely up-to-date with regard to the patholgy and to the aging process in general, if not so with regard to current interventional techniques for human clinical use.

The first book and medical articles that explained aging were published two decades ago, including Reversing Human Aging (1996) and the first two articles in the medical literature (both in JAMA, in 1997 and 1998). There are no earlier or more complete explanations of how aging works, nor of the potential for effective clinical intervention in aging and age-related disease. Since then, I have published additional articles and books that explain the aging process and potentially effective clinical interventions. The most recent, and most readable of these (The Telomerase Revolution, 2015) is meant for the lay reader and is available in 7 languages and 10 global editions. For those of you who want to know more, I encourage you to explore this book, which was praisde in both The London Times and the Wall Street Journal.

Finally, the focus will be the theory of aging; a theory that is valid, accurate, consistant with known data, predictively valid, and testable. This will not be a narrow discussion of the “telomere theory of aging”, which is a misnomer, but a detailed discussion of how aging works and what can be done about it using current techniques. A factual and accurate explanation of aging relies on telomeres, but also must addrss mechanisms of genes and genetics, gene expression changes and epigenetics, cell senescence and changes in cell function, mitochondrial changes and ROS, molecular turnover and recycling, DNA damage and cancer, “bystander” cells and “direct aging”, tissue pathology and human disease, and – above all – how we may intervene to alleviate and prevent such disease. The proof is not “in the pudding”, but in the ability to save lifes, prevent tragedy, and improve health.

The proof is in human lives.

This theory of aging has several key features. It is the only theory that accounts for all of the current biological and medical data. It is internally consistent. It is predictively valid: for the past 20 years, it has predicted both academic research results and the clinical outcomes of pharmaceutical trials accurately and reliably in every case. These predictions include the results of monoclonal antibody trials in Alzheimer’s disease, as well as other Alzheimer’s clinical trials, other clinical trials for age-related disease, and animal research (in vivo and in vitro). Perhaps the most fundamental feature of this theroy of aging is that it is an actual theory, i.e., testable and falsiable. A “theory” that cannot be disproven isn’t science, but philosophy. Many of what we think of as “theories of aging” cannot meet this criteria. If they cannot be disproven, they are not science, but mere will-o’-the-wisps.

If the theory of aging has a single name – other than the “telomere theory of aging” — it might be the epigenetic theory of aging. Despite misconceptions and misunderstandings about what it says (both of which I will try to remedy here), the epigenetic theory of aging has stood the test of time for the past two decades. It remains the only rational explanation of the aging process, while remaining consistent, comprehensive, and predictively valid. When it predicted failure of an intervention, the intervention has failed. When it predicted an effective intervention, the intervention has proven effective. Whether it’s the telomere theory of aging or the epigenetic theory of aging, in this series, we will proceed to get our conceptual hands dirty and look carefully at what happens when aging occurs, why it happens, where it happens, and what can be done about it. We’re going to go at this step-by-step, going into detail, and showing why we can intervene in both the basic aging process and human age-related diseases.

I doubt you’ll be disappointed.


Next blog:       1.1 – Aging, What is Isn’t

January 23, 2018

Aging and Disease: 0.1 – A Prologue

Aging and Disease

0.1 – A Prologue

Over the past 20 years, I have published numerous articles, chapters, and books explaining how aging and age-related disease work, as well as the potential for intervention in both aging and age-related disease. The first of these publications was Reversing Human Aging (1996), followed by my articles in JAMA (the Journal of the American Medical Association) in 1997 and 1998. Twenty years ago, it was my fervent hope that these initial forays, the first publications to ever describe not only how the aging process occurs, but the prospects for effective clinical intervention, would trigger interest, growing understanding, and clinical trials to cure age-related disease. Since then, I have published a what is still the only medical textbook on this topic (Cells, Aging, and Human Disease, 2004), as well as a more recently lauded book (The Telomerase Revolution, 2015) that explains aging and disease, as well as how we can intervene in both. While the reality of a clinical intervention has been slow to come to fruition, we now have the tools to accomplish those human trials and finally move into the clinic. In short, we now have the ability to intervene in aging and age-related disease.

Although we now have the tools, understanding has lagged a bit for most people. This knowledge and acceptance have been held back by any number of misconceptions, such as the idea that “telomeres fray and the chromosomes come apart” or that aging is controlled by telomere length (rather than the changes in telomere lengths). Academics have not been immune to these errors. For example, most current academic papers persist in measuring peripheral blood cell telomeres as though such cells were an adequate measure of tissue telomeres or in some way related to the most common age-related diseases. Peripheral telomeres are largely independent of the telomeres in our coronary arteries and in our brains and it is our arteries and our brains that cause most age-related deaths, not our white blood cells. The major problem, howevere, lies in understanding the subtlety of the aging process. Most people, even academics, researchers, and physicians, persist in seeing aging as mere entropy, when the reality is far more elusive and far more complex. Simplistic beliefs, faulty assumptions, and blindly-held premises are the blinders that have kept us powerless for so long.

It is time to tell the whole story.

While my time is not my own – I’d rather begin our upcoming human trials and demonstrate that we can cure Alzhiemer’s disease than merely talk about all of this – I will use this blog for a series of more than 30 mini-lectures that will take us all the way from “chromosomes to nursing homes”. We will start with an overview of aging itself, then focus in upon what actually happens in human cells as they undergo senesceence, then finally move downstream and look at how these senescent changes result in day-to-day human aging and age-relate disease. In so doing, when we discuss cell aging, we will get down into the nitty-gritty of ROS, mitochondria, gene expression, leaky membranes, scavenger molecules, molecular turnover, collagen, beta amyloid, mutations, gene repair, as well as the mathematics of all of this. Similarly, when we discuss human disease, we will get down into the basic pathology of cancer, atherosclerosis, Alzheimer’s, osteoporosis, osteoarthritis, and all “the heart-ache and the thousand natural shocks that flesh is heir to”. We will look at endothelial cells and subendothelial cells, glial cells and neurons, osteoclasts and osteoblasts, fibroblasts and keratinocytes, chondrocytes, and a host of other players whose failure results in what we commonly think of aging.

I hope that you’ll join me as we, slowly, carefully, unravel the mysteries of aging, the complexities of age-related disease, and the prospects for effective intervention.

December 1, 2017

Big Pharma: Still Looking for the Horse

About a century ago, in a small American town, the first automobile chugged to a stop in front of the general store, where a local man stared at the apparition in disbelief, then asked “where’s your horse?” A long explanation followed, involving internal combustion, pistons, gasoline, and driveshafts. The local listened politely but with growing frustration, then broke in on the explanation. “Look”, he said, “I get all that, but what I still want to know is ‘where is your horse?’”

About three hours ago, in a teleconference with a major global pharmaceutical company, I was invited to talk about telomerase therapy and why it might work for Alzheimer’s, since it doesn’t actually lower beta amyloid levels. I explained about senescent gene expression, dynamic protein pools whose recycling rates slow significantly, causing a secondary increase in amyloid plaques, tau tangles, and mitochondrial dysfunction. The pharmaceutical executive listened (not so politely) with growing frustration, then broke in on the explanation. “Look”, she said, “I get all that, but what I still want to know is how does telomerase lower beta amyloid levels?”

In short, she wanted to know where I had hidden the horse.

The global pharmaceutical company that invited me to talk with them had, earlier this year, given up on its experimental Alzheimer’s drug that aimed at lowering beta amyloid levels, since it had no effect on the clinical course. None. They have so far wasted several years and several hundred million dollars chasing after amyloid levels, and now (as judged by our conversation) they still intent on wasting more time and money chasing amyloid levels. We offered them a chance to ignore amyloid levels and simply correct the underlying problem. While not changing the amyloid levels, we can clean up the beta amyloid plaques, as well as the tau tangles, the mitochondrial dysfunction, and all the other biomarkers of Alzheimer’s. More importantly, we can almost certainly improve the clinical course and largely reverse the cognitive decline. In short, we have a new car in town.

As with so many other big pharmaceutical companies, this company is so focused on biomarkers that they can’t focus on what those markers imply in terms of the dynamic pathology and the altered protein turnover that underlies age-related disease, including Alzheimer’s disease. And we wonder why all the drug trials continue to fail. The executive who asked about amyloid levels is intelligent and experienced, but wedded to an outmoded model that has thus far shown no financial reward and – worse yet – no clinical validity. It doesn’t work. Yet this executive met with me as part of a group seeking innovative approaches to treating Alzheimer’s disease.

Their vision is that they are looking for innovation.

The reality is that they are still looking for the horse.

July 30, 2017

Of Dog, Wires, and Alzheimer’s Disease

Filed under: Alzheimer's disease,Biotech — Tags: , , — admin @ 5:23 pm

I have a dog. Without exaggeration or exception, she one of the most delightful dogs that I have ever had in my life, and I have had a great many dogs in my life. Like many dogs, she is captivated by squirrels. They are both the aim and the bane of her canine life. The other day, seeing one running along a telephone wire stretching from pole-to-pole above her head, she not only barked and chased it, she lept as high as possible, hoping to catch it. The squirrel ignored her, except to chitter and tease her futile efforts. Repeated failures did not deter my dog. Given her charming, but narrowly limited understanding of of the world, the best response to failure was to redouble her physical effort, so she barked even louder and lept even higher to catch the squirrel. To no avail. It never occurred to her that leaping at telephone wires would never capture the squirrel. In her own way, and for a dog, she is intelligent, hardworking, skilled, and energetic, but she will never catch the squirrel by leaping at telephone wires.

For decades, large (and small) pharmaceutical companies have been trying to cure Alzheimer’s disease. They can clearly see the goal above them, they have resources and intelligence enough for the effort and, despite universal failure, they continue to work even harder and leap even higher to cure Alzheimer’s. Repeated failures do not deter them. Given their charming and narrowly limited understanding of the world, the best response is to redouble their efforts, so they invest more money, invest more effort, and leap all the higher. To no avail. It never occurs to them that they are aiming at the wrong targets, without any understanding of the pathology and the underlying fundamentals of the disease. They are intelligent, hardworking, skilled, and energetic, but they will never catch Alzheimer’s by aiming at the wrong targets.

Or squirrels by leaping at telephone wires.

March 21, 2017

The Frustration of (Not) Curing Alzheimer’s

I am deeply frustrated by two plangent observations: 1) we squander scant resources in useless AD trials and 2) AD can easily be cured if we applied those same resources to useful AD trials. Applying our resources with insight, we will cure Alzheimer’s within two years.

The first frustration is that most pharmaceutical firms and biotech companies continue to beat their heads against the same wall, regardless of clinical results. Whether they attack beta amyloid, tau proteins, mitocondrial function, inflammation, or any other target, the results have been, without exception, complete clinical failures. To be clear, many studies can show that you can affect beta amyloid or other biomarkers of Alzheimer’s disease, but none of these studies show any effect on the clinical outcome. In the case of amyloid, it doesn’t matter whether you target production or the plaques themselves. Despite hundreds of millions of dollars, despite tens of thousands of patients, not one of these trials has ever shown clinical efficacy. Yet these same companies continue to not only run into walls, but remained convinced that if they can only run faster and hit the wall faster, they will somehow successfully breach the wall. They succeed only in creating headaches, accompanied by lost money, lost opportunities, and lost patients. The problem is not a lack of intelligence or ability. The researchers are – almost without exception – some of the most intelligent, well-educated, technically trained, and hard-working people I know. The irony is that they are some of the best 20th century minds I know. The problem, however, is that it is no longer the 20th century. If you refuse to adapt, refuse to change your paradigm, refuse to come into the 21st century, you will continue to get 20th century results and patients will continue to die of Alzheimer’s disease. Money and intelligence continues to be dumped into the same clichéed paradigm of pathology, as we aim at the wrong targets and misunderstand how Alzheimer’s works. And the result is… tragedy.

The second frustration is that we already know the right target and we already understand how Alzheimer’s disease works. We are entirely able to cure and prevent Alzheimer’s disease now. At Telocyte, we already have the initial resources we need to move ahead, but it is surprising how difficult it is for some people — wedded to 20th century concepts — to grasp the stunning potential, both clinically and financially of what we are about to do at Telocyte. We can not only reverse Alzheimer’s disease, but we can also cut the costs of health care while creating a stunningly successful biotech company in the process. We have the right tools, the right people, the right partners, and the sheer ability to take this through FDA trials. Already, we have several lead investors committed to our success. We are asking for a handful of additional investors, those who can see what the 21st century is capable of and who can understand why Telocyte is both the best clinical investment and the best financial investment in innovative medical care.


December 29, 2016

The Ethics of Gene Therapy for Alzheimer’s Disease

The Ethics of Telomerase Treatment


The rationale behind telomerase therapy was first published in the medical literature two decades ago1 and has been updated and supported in academic textbooks2 and a more recent book for the public3 as well. The theoretical basis was cogent, even twenty years ago, and evidence has continued to support the hypothesis since then, in human cells, in human tissues, in informal human trials, and in formal animal trials. The potential implications of telomerase interventions in human age-related disease are unprecedented, well-supported, consistent, and feasible. The surprise is not that this approach is practical, but that it has taken so long to get telomerase therapy into clinical trials.

The reasons for the delay are complex and subtle, but are part of human nature.

For one thing, the clinical use of telomerase requires a novel and more sophisticated understanding of the aging process itself – at the genetic and epigenetic level – than has been the case until recently. Whenever a new scientific paradigm comes into play – whether a geocentric solar system, biological evolution, quantum mechanics, relativity, or anything else – it takes time for us to outgrow previous, less accurate models and to accept a more complex, but more accurate understanding of reality. Reality is not a democracy and a consensus is no guarantee of truth.

Putting it bluntly: old theories never die, their proponents do.

A second problem is credibility. In the case of telomerase clinical trials, there have been a number of cases in which individuals or companies (impatient with the regulatory delays so common in modern drug development) have attempted “end runs” of social and regulatory acceptance. Unfortunately (and perhaps unfairly), these off-shore human trials are often judged as lacking credibility and this can also undercut the credibility of other attempts. If a company evades the FDA (or the accepted regulatory agencies in other countries, such as the EMA or CFDA) and runs small off shore trials their results are not only specifically disbelieved, but result in general disbelief, even of serious biotech endeavors that DO attempt to meet FDA requirements. Moreover, the companies that attempt “end runs” often seek publicity and the outcome can be a perception that while there is significant publicity, that’s all there is. Unfairly or accurately, the academic judgement becomes one of “incredible claims, but no credible data”. Fair or unfair, just or unjust, such is human nature and such is the nature of clinical research in today’s world.

A third problem is a general misunderstanding of the role of telomerase in cancer. Telomerase never causes cancer, although small amounts can be necessary to permit cancer. More striking, however, is the role of telomerase in genomic stability: telomerase upregulates DNA repair, drastically lowering the risk of cancer. Dividing cells – including cancer cells – require at least minimal telomerase, yet a significant presence of telomerase (and sufficiently long telomeres) is protective against cancer. Some have even suggested that cancer is a disease of the young, and attribute it to the presence of telomerase, but the clinical reality is that cancer increases exponentially with age and that this increase is directly attributable to the down-regulation of DNA repair due to telomere shortening. In short, telomerase can be used to prevent cancer.

A fourth problem is a naïve conception of the pathology that underlies Alzheimer’s disease (and other age-related diseases). Citing data on mice, genetically altered to express a human amyloid protein, they extrapolate the results to human Alzheimer’s patients without appreciating the complex cascade of pathology that actually occurs in humans, let alone the differences between mice and human patients.

Finally, some people argue with the ethics of treating Alzheimer’s disease in clinical trials at all, let alone by using gene therapy. One wonders whether they have ever spend a year or two watching a loved one slide down into the abyss. I have known hundreds, perhaps thousands, of Alzheimer’s patients and their family members. Almost without exception, most would do literally anything, try literally anything in an effort to find a cure. The pity of AD is that it is 100% fatal and there is NO effective therapy – at the moment. While few of us would risk an experimental gene therapy (even one as promising at telomerase) to treat wrinkles or osteoporosis (particularly since neither one is fatal), all of us would consider such therapy to treat Alzheimer’s disease. It is scarcely surprising that scarcely a day goes by without someone contacting me, asking about potential treatments for Alzheimer’s disease. These are not people who live in ivory towers, these are not people with a “degree in microbiology”, these are people who are deeply and personally affected by the tragedy.

They’ve BEEN there. They UNDERSTAND.

One critic of gene therapy noted that: “there are 7 patients killed by gene therapy clinical trials” (over the past 20 years). Compare this with the seven hundred thousand Alzheimer’s patients who died in 2016 alone of not having had gene therapy. Why would I choose to be one of 700,000 deaths per year?

For those of us who have spent decades treating dying patients, for those of us who have Alzheimer’s disease, and for those of us who are terrified by what is happening to those we love who have Alzheimer’s disease, the ethics of using gene therapy to try curing the most frightening disease on earth are clear enough.

The ethical weight lies on the side of compassion.



  1. Fossel: Reversing Human Aging (1996) . Banks and Fossel: Telomeres, cancer, and aging – Altering the human lifespan (JAMA, 1997). Fossel: Telomerase and the aging cell – Implications for human health (JAMA, 1998).
  2. Fossel: Cells, Aging, and Human Disease (Oxford University Press, 2004).
  3. Fossel: The Telomerase Revolution (BenBella Press, 2015).

November 22, 2016

Teaching Cells to Fish

Aging is the slowing down of active molecular turnover, not the passive accumulation of damage. Damage certainly accumulates, but only because turnover is no longer keeping up with that damage.

It’s much like asking why one car falls apart, when another car looks like it just came out of the showroom. It’s not so much a matter of damage (although if you live up north and the road salt eats away at your undercarriage, that’s another matter), as it is a matter of how well a car is cared for. I’ve see an 80-year-old Duesenberg that looks a lot better than my 4-year-old SUV. It’s not how well either car was made, nor how long either car has been around, but how well each car was cared for. If I don’t care for my SUV, my SUV rusts; if a car collector gives weekly (even daily) care to a Duesenberg, then that Duesenberg may well last forever.

The parallel is apt. The reason that “old cells” fall apart isn’t that they’ve been around a long time, nor even that they are continually being exposed to various insults. The reason “old cells” fall apart is that their maintenance functions slow noticeably and that maintenance fails to keep up with the quotidian damage occurring within living cells. If we look at knees, for example, the reason that our chondrocytes fail isn’t a matter of how many years you’ve been on the planet, nor even a matter of how many miles a day you spend walking around. The reason chondrocytes fail is because their maintenance functions slow down and stop keeping up with the daily damage. As it turns out, that deceleration in maintenance occurs because of changes in gene expression, which occur because telomeres shorten, which occur because cells divide. And, not at all surprisingly, the number of those cell divisions is related to how long you’ve been on the planet (how old you are) and how many miles you walk (or if you play basketball). In short, osteoarthritis is distantly related to your age and to the “mileage” you incur, but not directly so. The problem is not really the age nor is it the mileage; the problem is the failure to repair the routine damage and THAT failure is directly controlled by changes in gene expression.

So what?

The telomeres and gene expression may play a central role, but if your age and the “mileage” is distantly causing all those changes in cell division, telomere lengths, gene expression, and failing cell maintenance, then what’s the difference? Why bother with all the complexity? Why not accept that age and your “mileage” are the cause of aging diseases and stop fussing? Why not simply accept age-related disease?

Because we can change it.

The question isn’t “why does this happen?” so much as “what can we do about it?” We can’t change your age and it’s hard to avoid a certain amount of “mileage” in your daily life, but we CAN change telomeres, gene expression, and cell maintenance. In fact, we can reset the entire process and end up with cells that keep up with damage, just as your cells did when you were younger.

Until now, everyone who has tried to deal with only the damage (or the damaged cells) failed because they focused on damage rather than focusing on repair. For example, if you focus only on cell damage (as most big pharma and biotech companies do when they go after beta amyloid or tau proteins in trying to cure Alzheimer’s disease), then any clinical effect is transient and the disease continues to progress – which is why companies like Eli Lily, Biogen, TauRx, and dozens of other companies are frustrated. And small wonder. Or if you focus only on the damaged cells (and try removing them), then the clinical effect is not only transient, but will end up accelerating deterioration (as discussed in last week’s blog, see figure below) – which is why companies like Unity will be frustrated. Their approaches fail not because they don’t address the damage, but because they fail to understand the deceleration of dynamic cell maintenance that occurs with age – and fail to understand the most effective single clinical target. The key target is not damage, nor damaged cells, but the changes in gene expression that permit that damage, and those damaged cells, to lead to pathology. We can’t cure Alzheimer’s or osteoarthritis by removing senescent cells, but we can cure them by resetting those same cells.

Why you shouldn't kill senescent cells.

Why you shouldn’t kill senescent cells.

In the cases of removing senescent cells (an approach Unity advocates), wouldn’t it be better to remove the damaged cells and then reset the telomeres of those that remain? But why remove the damaged cells if you can reset them as well, with the result that they can now deal with the damage and remove it – as well as young cells do?

Why remove senescent cells at all?

While you could first remove senescent cells, then add telomerase so that the remaining cells could divide without significant degradation of function, why would you bother? You could much more easily, more simply, and more effectively treat all the cells in an aging tissue, reset their aging process and have no need to ever remove senescent cells in the first place. Instead of removing them, you simply turn them into “younger” and more functional cells. For an analogy, imagine that we have a therapy that could turn cancer cells into normal cells. If that were true, why would anyone first surgically remove a tumor? If you could really “reset” cancer cells into normal cells, there would be no need to do a surgical removal in the first place. While there is no such therapy for cancer cells, the analogy is still useful. Removing senescent cells is not only counter-productive, but (if we reset gene expression) entirely unnecessary.

Removal is unnecessary (both as to cost and pathology), risky, and medically contraindicated. You’d be performing a completely unnecessary procedure when a more cost-effective and reliable procedure was available. It would be exactly like removing your tonsils if you already had overwhelming data showing that an antibiotic was reliable, cheap, and without risk.

A cell with full telomere lengths – regardless of prior history – is already superior. The accumulated damage is not a static phenomenon, but a dynamic one. Reset cells can clean up damage. This is not merely theory, but supported well in fact, based on both human cells and whole animal studies. We shouldn’t think of damage as something that merely accumulates passively. All molecules are continually being recycled. The reason some molecular pools show increased damage isn’t because molecules denature, but because the rate of turnover slows, thereby allowing denatured molecules (damage) to increase within the pool.

Try this analogy: we have two buildings. One is run by a company that invests heavily in maintenance costs, the other is run by a company that cut its maintenance budget by 50%. The first building is clean and well-kept, the second building is dirty and poorly-kept. Would you rather raze the second building and then rebuild it or would you rather increase the maintenance budget back to a full maintenance schedule and end up with a clean building? This is precisely the case with young versus old cells: the problem is not the dirt that accumulates, the problem is that no one is paying for routine maintenance. There are cells that are “too senescent” to save, but almost all the cells in human age-related disease can be reset with good clinical outcome. There is no reason to remove senescent cells any more than (in the case of a dirty building), we need to send in the dynamite and bulldozers.

Too often, we try to approach the damage rather than looking at the longer view. Instead of addressing the process, we address the outcome. It’s like the problem that often occurs in global philanthropy, where we see famine and think we can solve the problem with food alone. While the approach is necessary – as a stopgap – many are surprised to find that simply providing free food for one year, results in bankrupt farmers and recurrent famines in the following years. Or we provide free medical care in a poor nation, then wonder why there is a dearth of medical practitioners in years to come, without realizing we have put them out of business and accidentally encouraged them to emigrate to someplace they can make a living and feed their families. We intend well, but we perpetuate the problem we are desperately trying to solve. Treating famine or medical problems, like treating the fundamental causes of age-related disease, is not simple and cannot be effectively addressed with band aids and superficial interventions, such as addressing damage alone or removing senescent cells. Effective clinical intervention – like effective interventions in famine or global healthcare – require a sophisticated understanding of the complexity of cell function, an understanding of the dynamic changes that underlie age-related pathology.

An adage (variously attributed to dozens of sources) about fish and fishing provides a useful analogy here:

Give a man a fish, and you feed him for a day.

Teach a man to fish, and you feed him for a lifetime.

If we want to intervene effectively in age-related diseases – whether Alzheimer’s, osteoarthritis, or myriad other problems of aging – we shouldn’t throw fish at medical problems.

We should teach our cells to fish.


November 15, 2016

Close to a Cure

We are now within two years of a cure for Alzheimer’s disease.

What a brash and disruptive claim! What hubris! Yet events are coming together, underlining a new and far more complete understanding of the disease, illuminating the cause, supporting the ability to intervene, safely and effectively. We finally see a way to intervene in the basic pathology, underlining the potential to both prevent and cure Alzheimer’s disease.

But why has it taken so long? Why was Alzheimer’s disease first defined 110 years ago, and yet remains totally beyond our ability to intervene even now? Why have all other approaches, whether those of big pharma or those of biotech, failed utterly? Why has not a single clinical trial shown any ability to change the progress of this frightening disease? Why is Alzheimer’s disease not only called “the disease that steals human souls”, but also called the “graveyard of companies”? Why has every single approach (which has at most shown only an effect on biomarkers, such as beta amyloid), still failed to show any change in the cognitive decline in patients with this disease? Why have we failed universally, until now?

Because every approach has concentrated on effects, not on causes.

Currently, most approaches target beta amyloid, many target tau proteins, and some target mitochondrial function, inflammation, free radicals, and other processes, but no one targets these problems as a single, unified, overarching process. Alzheimer’s isn’t caused by any one of these disparate processes, but by a broader, more complex process that results in every one of these individual problems. Beta amyloid isn’t a cause, but a biomarker. Equally, tau proteins, phosphodiesterase levels, APOE4, presenilins, and a host of other markers are effects, not causes. The actual cause lies upstream and constitutes the root cause of the dozens of separate effects that are the futile downstream targets of every current FDA trial aimed at Alzheimer’s disease. Understanding this, we will be targeting the “upstream” problem, rather than the dozens of processes that others target individually and without success. Our animal studies support the ability to effectively intervene in human disease: when we say that we are about to cure Alzheimer’s disease, we base claim that on a clear and consistent theoretical model, supported by equally clear and consistent data.

Within the next few months, we will begin our FDA toxicity study, preparatory to obtaining an IND that will permit us to begin our FDA human trial. Our toxicity study will take 6 months and will meet FDA requirements for human safety data. Our first human trial is planned to begin one year from now and is intended to show not only safety, but a clear efficacy. We will include a dozen human volunteers, each with (not just early, but) moderate Alzheimer’s disease and our human trial will last 6 months, including a single treatment and multiple measurements of behavior, laboratory tests, and brain scans. We expect to show unambiguous cognitive improvement within that six-month period. We are confident that we cannot merely slow, not merely stop, but reverse much of the cognitive decline in our twelve patients. We intend to demonstrate an ability to cure Alzheimer’s disease clearly and credibly.

Curing Alzheimer’s requires investments of money, time, and thought. The toxicity study costs 1 million dollars; the human trial costs 2.5 million dollars. Telocyte has half a million dollars committed to this effort and at least one group of investors with a firm interest in taking us all the way through the human trials. We are close and we grow closer each day.

After 110 years, we are about to cure Alzheimer’s.

November 8, 2016

Revolution in Medicine

Every pharmaceutical firm, every biotech company, every hospital, every clinic, and every conference makes revolutionary claims, albeit seldom with any logic or thought behind the claims. Every product is a “revolutionary” therapy, every surgery is a “revolutionary” procedure, and everyone has a “revolutionary” way of looking at clinical medicine. Reality is strikingly different. Despite claims to the contrary, almost all advances in medicine are accretionary, not revolutionary. About sixty percent of all FDA applications for “breakthrough” status are turned down for not being breakthroughs, but merely incremental advances (if that). Even granting a third of these applications is overly kind, but then breakthroughs, like revolutions, are remarkably rare. I am reminded of my years consulting for hospitals around the world, where I was entertained to find every hospital, in every town, in every country, bragging that they were ranked as “one of the best ten hospitals!” Sometimes, they bragged that they were THE best hospital. Somehow, it appears that thousands of hospitals are among the best ten hospitals and hundreds are THE best hospital. In the entire world or on that block?

It clearly depends on who’s counting and on who does the ranking.

Therapies are much the same: they are seldom “the best” (in the world?) and they are almost never revolutionary. To the contrary, almost all current therapy is based on incremental change: we find a slightly better statin, an antibiotic with slightly less resistance (at least this year), and a procedure with a slightly lower risk. We rank our interventions by statistical significance and we deal with percentage points in the adverse effect profile. Scarcely the stuff of revolution.

We can do better; much better. To do so, however, requires both an open mind and a very disciplined one. We need both creativity and intelligence to envision a path to revolutionary therapies. If we do so, we may be able to cure diseases that are thought to be “incurable”, a true revolution I both clinical thinking and clinical practice.

Many people, in a totally practical vein, think of diseases in three categories. The first includes those diseases that we have “cures” for, by means of vaccines, antibiotics, and routine surgeries (think of tetanus, cellulitis, and appendicitis). The second category includes diseases for which we have no cure yet, but for which we see a cure on the horizon (think of treating sickle cell anemia with gene therapy). This second category includes type 1 diabetes: while we use insulin to good effect, we eagerly imagine the days when we simply replace the missing cells in the pancreas and truly cure diabetes. While we have – or imagine that we may soon have – true cures for these diseases in both the first two categories, the third category brings a sense of futility. When it comes to age-related disease (think of Alzheimer’s disease, cardiovascular disease, osteoporosis, etc.), we are caught up by the assumption that while we can treat symptoms, use grafts or stents, lower the risk factors, or replace the damaged part (a total knee replacement comes to mind), we will never be able to entirely prevent or cure the underlying disease. After all, they’re simply the outcome of aging, yes? And who could possibly change the aging process?

Oddly enough, we already have.

We first showed we could reverse cell aging in 1999, followed by the reversal of tissue aging (in the laboratory) in the following few years. The question isn’t “can we reverse the aging process in human cells or tissues”, but “can we reverse the aging process in human patients”? Can we take someone with age-related disease, treat them, and reverse the disease reverse at the cellular and genetic levels? Can we prevent and cure age-related disease? Based on both theory and animal data, the answer is almost certainly to be “yes, we can”. All it requires is intelligence, a modicum of work, and a small commitment of funding.

Instead of treating Alzheimer’s as something to live with, we can treat it and have it be something we can live without. Only then we will have a true revolution.

November 1, 2016

Making Things Worse

Imagine a factory which is operating at capacity, with a thousand workers. Some of the workers are doing a great job, but some are ill and not working hard. In fact, they are actively interfering with those who are working hard. In this factory, you can’t hire anyone new, so you have two choices: you can fire the bad workers or you try to improve their health. If you simply fire the bad workers, you have increased the work load for those who remain. Not surprisingly, they begin to get tired and ill as well, so the factory ends up failing even faster and before you know it, everyone is out of a job. On the other hand, if you can improve the health (and the attitude) of the workers who are tired and ill, the factory can become a success.

The factory is human tissue; the workers are your cells.

Let’s look at an example, such as the cells in your knee. Over time, the chondrocytes divide, become gradually more senescent, and begin to fail. The result is osteoarthritis. If you have mild osteoarthritis, you might (naively) consider simply removing senescent cells. This reliefs some of the inflammation and removes the cells that aren’t doing a good job (the tired workers), but the result is that you’ve just asked all the remaining cells to take up the slack (increased the work load for the remaining factory workers). In order to replace the cells that you’ve removed, the remaining cells now have to divide, which accelerates their own senescent changes, and hastens the failure of the entire tissue. In the case of the knee joint, the osteoarthritis improves temporarily, but you’ve just accelerated osteoarthritic changes in the long run. Instead of a slow joint failure, you’ve ensured that it fails even faster.

Several people have, in a charming burst of innocence, recommended that we do just that. Instead of resetting senescent cells and restoring cell and tissue function, they want to remove senescent cells in older tissues. Their hope is understandable, but their understanding is simplistic. Studies show that you may see temporary improvement in inflammation and secretory profiles, but what about long term risks? The problem is that those who want to kill off senescent cells lack a full appreciation of the dynamic pathology and the cellular consequences. They offer a simplistic view, but biology is seldom simplistic.

Why you shouldn't kill senescent cells.

Why you shouldn’t kill senescent cells.


Consider the knee again. A common concern is that of chondrocyte senescence (leading to osteoarthritis) in professional basketball players. Because of repetitive high-impact trauma, they lose chondrocytes at an accelerated rate compared to people whose knees are not subject to traumatic cell loss. The remaining chondrocytes divide to replace the lost chondrocytes, accelerating telomere loss, and accelerating osteoarthritic changes. The clinical result is due to tissue failure at an early age.

Those who are trying to treat tissue senescence by selectively removing senescent cells (instead of resetting them to a normal pattern of gene expression) are causing a transient improvement in tissue function, coincident upon the removal of dysfunctional, senescent cells (temporarily decreasing inflammatory biomarkers, for example), but the longer-term result is to accelerate cell senescence in all remaining cells. The result is a transient hiatus in inflammation and other biomarkers of cell senescence, followed by a more rapid decline in cell and tissue function. In the case of OA, for example, the outcome is to relief symptoms temporarily, only to then ensure a more rapid failure of the joint.

Our analogy remains apt. If you have a group of workers in a factory, some of whom are suffering from fatigue and are no longer producing, you have two possible interventions. Intervention #1 might be to fire all the tired workers, but the long-term result is that you increase the workload and failure rate among the remaining workers. Intervention #2 would be to find a way to restore the energy and interest among those workers who are fatigued. The analogy is a loose one, but the outcomes are predictable. Removing the “tired” cells within a tissue will accelerate pathology. Resetting the “tired” cells within a tissue will resolve pathology.

If you want to cure age-related disease, the solution is not to kill senescent cells, but to reset their gene expression to that of young cells.


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