Sunday, May 20, 2018

Slowing Down Aging

Do ugly older people die younger?

In 2012 Ian Deary and his colleagues with the University of Edinburgh, tested whether older adults who looked less attractive died before their more attractive peers. The authors asked people to rate the photographs of 292 older adults aged 83 years of age. They rated the photographs on how old healthy, attractive intelligent and happy they looked. They also looked at how symmetrical the faces are (the left side of the face is proportionally similar to the right). Then the authors followed the people in the photographs over a 7-year period to see which ones died first. They were trying to see if we can predict who dies first. What they found is that the main predictor was how old they were judged to be. After accounting for how old they looked, this was followed by how healthy they were rated from the photographs. Looking more attractive did not have any advantage after accounting for how old they looked. It seems, looking older rather than looking less attractive predicted an early death. But the two are related—looking attractive is also related to looking younger. Age determines how we judge people as attractive.

Look around and you see people that look better than others—and by better of course, I mean younger. We naturally assume that looking younger is healthier and more attractive. That dress that takes 10 years off, or a haircut that makes you look younger are all compliments. And we can easily speed up aging by stress for example. We know of people that have gone through a trauma in their life and they “aged” quickly. We have this idea of the process of aging that can speed up or slow down. One of the main stressors in our modern lives is money, and lack of it. We know that rich people live longer, but are they also more attractive? Such a relationship could work from both sides with attractive people getting more preferential treatment and becoming more successful which in turn allows them to make their life better.

Susanne Huber and Martin Fieder 2014 found rich your parents predict facial attractiveness in their children at young adulthood (17-20 years old). Of course, attractiveness is mainly due to the symmetry of the face. In 2001 Deborah Hume and Robert Montgomerie with Queen's University, Canada, examined this symmetry. What they found is that women symmetry was best predicted by how fat they are and by previous health problems. For men, facial attractiveness was best predicted by how rich they are and their how comfortable their environment is. Attractiveness seems to be positively related to the degree to which an individual cope with stress growing up. For women it is mainly their weight and health, for men it is mainly money.

The economics of beauty has been written about extensively. Daniel Hamermesh in 2011 consolidated some of these thoughts in his book Beauty Pays. There is no age limit for vanity. In the US single women aged seventy years and older spend over forty-three minutes a day in grooming. From archeological sites we can see that grooming behavior extends across the world and throughout human history. Of course,  what we think of beautiful differs by country, culture and across time, but there are certain constants and being younger is one of them. There are no older Venuses nor older Davids. Old age is not paraded as examples of beauty. Never was across any culture.

Which is why women are judged more harshly for their looks than men, we also see ageing as being more determinantal to women in how they are treated by others. For people who weren’t born to have attractive features or have been in an accident, Hamermesh mentions that cosmetic surgery has been a solution for many older adults including increasingly for older men. In 2016 the US spent $16.4 billion on cosmetic procedures. This is one and a half times more than the total economic productivity of Malta ($10.95 billion in 2016). Americans spend more on having body parts modified than Malta’s total economy. And one of the main group is those entering into older age, 55 years and older.

In 2016, those over 55 years and older had 4.1 million total cosmetic procedures, an increase of 3-4% in procedures since the previous year. Of these 387,000 were surgical procedures, and 3.7 million were minimally-invasive procedures (injections and friction). For middle aged adults the main surgical procedures were eyelid surgery, facelift, dermabrasion, liposuction and forehead lift. Minimal invasive surgery included in order of popularity; Botox, soft tissue fillers, chemical peel, laser skin resurfacing and microdermabrasion. While most popular procedures among young adults focus on their bodies, older adults are apparently more concerned about more visible features, such as their faces. Older adults know that they are being judged by how old they look and their faces are their calling cards.

For these older adults who have had cosmetic surgery, regardless of how young they look, they will not prolong their time of death. What they are fighting is not death but being judged. In a world that judges attractiveness by how old we look older adults are in greater and increasing numbers resorting to fighting it b attempting to look younger. But it is the judgment that needs to change. Such vanity discrimination draws striking parallels with ageism, racism and sexism. The only way to confront these is not by becoming the “other” but by eliminating the category of other altogether.

© USA Copyrighted 2018 Mario D. Garrett

References

Dykiert, D., Bates, T. C., Gow, A. J., Penke, L., Starr, J. M., & Deary, I. J. (2012). Predicting mortality from human faces. Psychosomatic medicine, 74(6), 560-566.

Huber, S., & Fieder, M. (2014). Effects of parental socio-economic conditions on facial attractiveness. Evolutionary Psychology, 12(5), 147470491401200514.

Hume, D. K., & Montgomerie, R. (2001). Facial attractiveness signals different aspects of “quality” in women and men. Evolution and human behavior, 22(2), 93-112.

How Films Portray Aging

In our increasingly digital world, we get an enormous amount of information from films. Our imagination has always been fired up by films. A relationship that has endured since the first films.  How older people are portrayed in film is best described through the interpretation of a narrative arc. An arc is the linear development of a story—a beginning, a middle and an end. 

One of the first films describing a simple story about older people is the 1952 Japanese film Ikiru by the acclaimed director Akira Kurosawa—acclaimed for the Seven Samurai, Rashomon, and Ran. Ikiru has a fairly simple narrative arc. An older man who worked in an office all his life, on the cusp of retirement, is informed that he has terminal cancer. The narrative arc focusses on the main character in the film attempting to find meaning and leaving behind a legacy in his life before he dies. This simple story highlights that after one’s entire life spent doing what you are supposed to do—work, maybe family—that at the end what is important is relationships. At the end, he finds some solace among his younger mates, where he finds friendship.

This narrative arc of an older man at the end of life, was further developed by another seminal director, Ingmar Bergman who in 1957 wrote and directed Wild Strawberries. Filmed in black and white, perhaps in homage to Ikiru, the film goes further in search of the meaning of one’s life. Following a fairly similar story of an accomplished professor, Wild Strawberries explores the question of what was it all about? We do not have ambitions for getting old, and once we get there, we remain without a plan. Admired but not loved, the professor starts to explore what the continuation of his story in older age should be. Like Ikiru, relationships seem to be the answer. Such a conclusion is not far-fetched from what we observe at the end of life.

In 2012 Bronnie Ware, an Australian palliative care nurse, wrote The Top Five Regrets of the Dying: A Life Transformed by the Dearly Departing. Our two male protagonists in Ikiru and Wild Strawberries follow these regrets. These misgivings focused on having unfulfilled dreams and unrequited loves. Not having the courage to follow their dreams, where (mostly) men tended to regret working so hard. Stifling feelings in order to settle for a mediocre existence. And not staying in touch with their friends and loved ones. And the final regret is not allowing oneself to be happy. They got stuck in a rut. The agreement between the narrative of these two films and the five regrets of dying people is stunning.

Some films on aging tend to start off with a negative view of aging, and then transforms into a story about friendship and family. That it is not too late to address past regrets.  But what if this transformation did not take place? If the negative view of aging remains without the salvation of a new-found story for older age? This is the story of the two characters in the 2015 Italian film Youth.

Paolo Sorrentino’s film centers on two close friends sharing a vacation at an exclusive Swiss spa. One is a film director who continues producing the same kind of films, surrounded by increasingly younger writers. While the other character is a music composer who has decided to retire. The composer stopped composing—to the chagrin of many—because of his wife’s dementia which he hid from everyone including his daughter. He made changes that address this trauma and his aging. Negative events in life change our story sometimes for the better. We realize what is important. In contrast, the other character, the director, only had one story—to remain doing what he did in the past. He did not have a different story for when he got old, and the quality of his work diminished. At the end, his suicide was the only answer to his failing career since he did not have a plan B, an evolving story for getting old.

We also place people in a story. We create a cage for them. Do a little exercise with me.

Let’s imagine that you have a 100-year-old woman that you are going to interview. What is the single question that you will ask her. Write it down. Then assume that you have a 16year-young girl coming to be interviewed. What single question would you ask? Write it down.

The prediction is that you probably ask the older woman about her past and the younger woman about her future. You have already hemmed them into your view of what their story should be.

To age successfully we must have a story that goes beyond adulthood—to extend into older adulthood. Our story is important because it is how we conduct our life, including into older age. What films teach us is that others can influence our story about getting older.

© USA Copyrighted 2018 Mario D. Garrett

Trailers on Youtube
Ikiru: https://www.youtube.com/watch?v=yCSiL2wmxuE
Wild Strawberries: https://www.youtube.com/watch?v=0RzOCwer-gc
Youth: https://www.youtube.com/watch?v=-T7CM4di_0c


All Demented Sinners


In 2011 Heiko Braak and his colleagues did something that no one else had done before. He looked at dementia in the brains of young children. By dissecting 2,332 brains ranging in age from 1 to 100, what he found was to change how we see disease. Only 10 people had complete absence of Alzheimer's disease related biology. Every person over 25 years of age had Alzheimer's disease biomarkers. Without any exceptions. Even among children under 10 years of age, one in five already had the Alzheimer’s disease signs. Every adult is sick with the disease. Heiko Braak and his wife Eva are known for their stages of dementia when in 1991 they published the six stages of dementia, that we know as Braak-Braak stages So they know a few things about the disease.

The finding that every adult has some of the disease that contributes to Alzheimer’s disease was not much news until this year. In 2018 the United State National Institute on Aging—an agency set up in 1976 to explore ways to promote the health of older adults—sponsored a new way to define Alzheimer’s disease. This new framework used the biology of the disease alone, ignoring how the disease is expressed. For the first time in the history of Alzheimer’s disease we are defining it not by how it looks—the loss of memory, possibly behavior changes and mood swings—but by the biology alone. The problem, as Heiko Braak found, is that by using the biology as an indicator of the disease this makes all of us suffering from Alzheimer's disease. 

Similar to the catholic church and original sin, where everyone is born with sin that eventually takes away the freedom of will, similarly we are told, Alzheimer’s disease is already in all of us and will eventually take away our freedom of will too. There are a lot of similarities. We are move science back to religion. But unlike the original sin were baptisms somewhat absolves us from this fate, with Alzheimer’s disease there is no cure and no way of absolving the disease. We are doomed whether we show dementia or not. Even healthy adults show the biology of the disease, there is no escaping.

This new way of diagnosing Alzheimer’s disease is dangerous. Not only for hospitals and clinics that have to deal with this new definition, but also for the legal aspects. What if a court argues that you are an incompetent witness (say someone stole money from you) because they can prove that you have Alzheimer’s disease and therefore do not have reliable memory. There are many other examples. Examples in real life today where the diagnosis of Alzheimer’s disease reduces your value as a witness in court. In the U.S. a diagnosis of Alzheimer’s will automatically revokes your driving privileges. You lose your driving license by the time you leave the doctor’s office (it is reportable disease that goes directly to the motor vehicle department.). If you have business loans you will likely lose those too. The repercussions of receiving a diagnosis of Alzheimer’s disease might also land you in a nursing home, whether you want to or not. This would be disastrous if all of these negative things happened when the person is still behaving normal. You and I reading this now.

The only group to benefit from making everyone an Alzheimer’s disease patient are drug companies. Most of the researchers involved in this new definition of Alzheimer’s disease have investments in and connections with large drug companies. Some of the authors reported working for the drug companies themselves. In 2011 such conflict of interests in France resulted in their guidelines being withdrawn. Researchers working for French Health Authority that issued guidelines for the treatment of type 2 diabetes and Alzheimer's disease was withdrawn by France’s highest administrative court. The court ruled that the potential bias and undeclared conflicts of interest among the authors “contravened national law on conflicts of interests and the agency's own internal rules.” According to a Consumer Report in 2102 Alzheimer's drugs cost a lot and help just a little. None work without side effects and none work long term.

There is a certain attitude of playing god. Telling nature that it made a mistake and then trying to fix it. Perhaps the disease of dementia is not caused exclusively by this biology. As so many researchers have been saying for more than one hundred years. The brain is the most complex organ in the universe. Many things can go wrong (wrong to us anyway, but perhaps this is nature’s way.)  The effect of this new method of determining whether someone has Alzheimer’s disease is that we begin to lose trust in our doctors. Looking at just the biology is not what doctors are trained for. They are trained to look at the expression of the disease. In a way this biological way of looking at disease side steps doctors’ experience and skill at diagnosing and makes everyone a patient for drug companies.

© USA Copyrighted 2018 Mario D. Garrett

References

Braak, H & Braak, E. (1991). "Neuropathological stageing of Alzheimer-related changes". Acta Neuropathologica. 82 (4): 239–59.

Braak, H., Thal, D. R., Ghebremedhin, E., & Del Tredici, K. (2011). Stages of the pathologic process in Alzheimer disease: age categories from 1 to 100 years. Journal of Neuropathology & Experimental Neurology, 70(11), 960-969.

Jack, Clifford, David A. Bennett, Kaj Blennow, Maria C. Carrillo, Billy Dunn, Samantha Budd Haeberlein, David M. Holtzman, William Jagust, Frank Jessen, Jason Karlawish, Enchi Liu, Jose Luis Molinuevo, Thomas Montine, Creighton Phelps, Katherine P. Rankin, Christopher C. Rowe, Philip Scheltens, Eric Siemers, Heather M. Snyder & Reisa Sperling (2018) NIA-AA Research Framework: Toward a biological definition of Alzheimer's disease. Alzheimer's & Dementia: The Journal of the Alzheimer's Association, 14(4), 535–562.

Jack C, Bennet D.A., Blennow K. et al (2018) NIA-AA Research Framework: Toward a biological definition of Alzheimer's disease. Alzheimer's & Dementia: The Journal of the Alzheimer's Association, Volume 14 , Issue 4 , 535 – 562. Supplemental Material accessed online 5/8/2018: https://www.alzheimersanddementia.com/cms/attachment/2119162008/2089988545/mmc1.docx

Lenzer, J. (2011). French guidelines are withdrawn after court finds potential bias among authors. BMJ 342: d4007


Wednesday, May 9, 2018

A Critique of the 2018 National Institute on Aging’s Research Framework: Toward a biological definition of Alzheimer’s disease


THIS POST HAS BEEN CENSORED AND UNPUBLISHED FROM  PSYCHOLOGTODAY.COM

Abstract
Shame on the National Institute on Aging (NIA) for sponsoring a new way of defining Alzheimer's disease based on biomarkers (plaques and tangles). Heiko Braak in 2011 after dissecting 2,332 brains ranging in age from 1 to 100 found that only 10 cases had complete absence of Alzheimer's disease related biology. Every person over 25 years of age had Alzheimer's disease biomarkers. The new framework sponsored by the NIA makes every older person liable for a diagnosis of Alzheimer's disease. The pharmaceutical connections of most researchers involved brings into question the intent of this framework. This article details the scientific argument against using biology as the only indicator of the disease while ignoring the clinical aspects. The conclusion advocates for a careful reassessment of an emerging eugenics movement where biological markers are becoming more readily relied on when the science supporting these indicators remains incomplete.

Introduction
After more than a century of research the National Institute on Aging and the Alzheimer’s Association (NIA-AA) are yet again reverting to the original century-old definition of Alzheimer’s disease. A definition which Emil Kraepelin—Alois Alzheimer’s supervisor—hastily formalized as a “new disease” in 1911. Published in 2018, this recycled definition is the NIA-AA latest Research Framework: Toward a biological definition of Alzheimer’s disease and was headed by Clifford Jack (referred to from now on as the Framework; Jack, et al, 2018).

The Framework relies on the plaques and tangles as the signature of Alzheimer’s disease, while overall neurological damage defines severity of Alzheimer’s disease. This time around, in contrast to the earlier 2011 Guidelines (Jack et al, 2011), this Framework ignores the clinical features of the disease. This is important because for the first time the clinical aspect of the disease—what we think of as Alzheimer’s disease which is how it is expressed through loss of memory, changes in mental capacities and even mood and personality changes—will be ignored in preference to its biological clues. By doing so the authors usher in a new dawn of disease classification. This new biological definition is based on three types of information: [A] amyloid beta deposition, [T] pathologic tau, and [N] neurodegeneration. Referred to as the AT(N) [see note below for a more detailed description].

With eight different AT(N) biomarker types this Framework is un-wielding in its confusion. But the confusion is not in its complexity but in its logic. The authors make the illogical and unsubstantiated claim that “A biological rather than a syndromal definition of AD [Alzheimer’s disease] is a logical step toward greater understanding of the mechanisms underlying its clinical expression.” (Jack, et al, 2018; p.536). That Alzheimer’s disease can only be diagnosed through these biological markers (biomarkers) while ignoring the real disease, its clinical expression. The authors argue that the clinical and neuropathological features of the disease are “…two very different entities…” (Jack, et al, 2018; p.536) and that “…cognitive symptoms are not an ideal way to define AD [Alzheimer’s disease]” (Jack, et al, 2018; p538). As a vehicle for scientific exploration, understanding and ultimately cure Alzheimer’s disease, the Framework ignores science, obfuscates methodology, and fudges outcomes in order to drive through an agenda based on pharmaceutical (in contrast to scientific) considerations. This paper lays out the argument for this assertion. There are serious repercussions from this approach but it is the lack of scientific rigor that will eventually expose this approach for what it is, a sham. This paper exposes the lack of scientific methodology utilized by the NIA-AA in reaching their conclusion.

A clinical disease—a disease that is experienced or has observed consequences—is now being argued to be exclusively a biological disease. But Alzheimer’s disease is only important because it is a clinical disease. If everyone that has the biomarkers do not express the disease then there would be no interest in research. It is of no consequence what the biology is if the disease is not experienced or observed. By reversing this truism, that the biology is more importantly than the outcome of the disease, the authors are transforming how we look at health and ill-health.  A transformation that the authors of the Framework concede is a “…a profound shift in thinking.” (Jack, et al, 2018; p.538.) The profound shift is also found in the lack of scientific method employed. But the authors protect this radicalism “…dementia is not a “disease” but rather is a syndrome composed of signs and symptoms that can be caused by multiple diseases, one of which is AD” (Jack, et al, 2018; p.538). Admitting that what they are studying can be one of many causes of Alzheimer’s disease and “The fact that most dementia is multifactorial presents a challenge both for diagnosis and treatment.” (Jack, et al, 2018; p.545). We are guaranteed no scientific road map in this Framework. The authors also acknowledge that we do not know how to start: “Cut points must be determined, and age norming biomarker cut points is controversial.” (Jack, et al, 2018; p.550) “The distinction between normal aging and age-related disease has been debated for decades…and we do not presume to settle this here.” (Jack, et al, 2018; p.550). Again, the Framework provides no structure for research on the real issues of aging, despite mounting evidence that dementia is not part of the normal aging process (e.g., Nelson, et al, 2011). We still do not have a framework for studying diseases related to aging as pathology rather than as aging. For a research framework the authors were laisse faire when it came to dictating “The committee avoided taking a proscriptive approach to these methodologic issues under the assumption that this was best left to expert work groups and individual research centers.”  (Jack, et al, 2018; p.551). But research centers do not determine these methodological issues, their sole objective in their research company—whether private or university-based laboratories—is to gain funding or monetize a cure.

That biology contributes to and is part of the process of Alzheimer’s disease is not contested. But to argue that the biology—the biological markers of the disease, its neuropathology—is purely the disease contradicts a wealth of evidence. The Framework is more of a research policy rather than a scientific paper and is therefore devoid of scientific merit. It was published even though biomarkers density and cutoff points through “universal standards have not yet been established.” (Jack, et al, 2018; p.551).

The Framework’s proposition is premature and wrong. It ensures that all older adults have Alzheimer’s disease. Older adults that do not have plaques and tangles in their brains have not been identified. As a result, older adults are automatically branded as suffering Alzheimer’s disease which makes this new approach ageist.  And such sensitivities are overwhelmed by the hubris of the authors when they admit that “Up to 60% of CU [cognitive unimpaired] individuals over age 80 years have AD [Alzheimer’s disease] neuropathologic changes at autopsy or by biomarkers…Thus, using a clinical diagnosis of ‘AD’ to ascertain absence of disease is associated with an error rate exceeding 50% in the elderly.” (Jack, et al, 2018; p.552). “However, it is increasingly recognized that neurodegeneration/ injury, even in classic AD [Alzheimer’s disease] brain regions, also occurs in non-AD conditions. This is particularly so in elderly individuals where comorbidities are common.” (Jack, et al, 2018; p.539).  The same Framework conceded a high rate of false negatives, with ten to thirty percent of autopsies of individuals with Alzheimer’s disease do not show these biomarkers. While among those still alive, a similar proportion of Alzheimer’s disease patients have normal amyloid PET or CSF Ab42 studies (Jack, et al, 2018). While in contrast there are many false positives, with thirty to forty percent of cognitively unimpaired elderly persons having the biomarkers at autopsy and at PET and CSF screenings (cited in Jack, et al, 2018). Averaging ten to forty percent false positive and false negatives does not form a solid foundation to develop a purely biomarker theory of Alzheimer’s disease. But if there is one study that should demolish the validity of this Framework is the study conducted in 2011 by Heiko Braak and his colleagues from the University of Ulm, in Germany. They looked at 2,332 brains of people that died from various causes from a number of different hospitals. The sample was not random, and a convenience sample, but t also included children. This is the first time that children’s brains were studied for dementia. From this study only 10 brains showed a complete lack of disease (less than half one percent) (Braak, et al, 2011). All of these cases where in people aged 23 years and younger. By the Framework’s criteria, all adults already have Alzheimer’s disease. Such criterion makes no sense unless you are a pharmaceutical company. In research defining all adults as suffering a disease limits the capacity to differentiate and limits what you could study. The criterion becomes unreliable with an adult population.

In addition, there is also a statistical problem to add to the biological problem. Older adults tend to have more neurological variances then younger adult populations. Such variance become greater among the older population—known as heteroscedasticity. Making a specific diagnosis becomes increasingly more difficult among older populations. For neurologists separating Alzheimer’s disease from other co-existing neurological diseases becomes very difficult and impossible in most cases. Dementia among older adults might have outward behavioral similarities, but the inward clinical expressions are very different because there are so many other co-morbidities present. For example, it is rare with older adults that a brain disease occurs in isolation from other type of (non-cognitive) diseases such as depression (Wagner et al, 2011) and anxiety (Guziak & Smith, 2014). While multiple comorbidities exist, isolating the disease includes both a clinical problem as well as a neurological one (Qui, DeRonchin & Fratiglioni, 2007). As a result, most dementias are misdiagnosed (Nielsen, 2011; Black & Simpson, 2014; Sayegh & Knight, 2013).

Explaining why a U.S. federal agency—the National Institute on Aging (NIA)—established to address the health needs of older adults, is pushing for an erroneous approach to study Alzheimer’s disease that will wrongly identify a disease among all of its constituents—older adults—attests to the overwhelming power of the pharmacological industry in subverting the NIA’s primary and sole task—protecting older adults. A cursory look at the business affiliation of some of the primary authors of the Framework identifies thousands of conflicts of interest (Jack et al, 2018; supplemental material).

There are both political as well as methodological/statistical deficits and to understand both it is important to understand the context why such conscious mistakes are propagated.

History
Summarizing research on dementia remains elusive because there is an abundance of research being produced across many technical disciplines. Driven exclusively by money, whether private pharmacological investments or federal and (international) states funding, research is mostly directed at monetizing a cure. There are some notable exceptions. Details of such work, some more impressive than others, divert researchers from an overview of the general health of the research itself. In 2017, Gill Livingston and her colleagues in reviewing dementia prevention, intervention, and care report that “…around 35% of dementia is attributable to a combination of these nine risk factors; early education up to age 11 or 12, hypertension, obesity, hearing loss and later-life depression, diabetes, physical inactivity, smoking and social isolation.” (Livingston, et al, 2017; p.14) While at the same time arguing that in comparison, eliminating the main genetic correlate (Apolipoprotein E) will only result in a 7% reduction in incidence. There is a resistance to acknowledging that what will truly cure, or at least delay dementia and Alzheimer’s disease is preventive care and lifestyle choices. That pharmacological interests benefit from this resistance is not by chance.

After enormous resources invested over the last 100 years to research Alzheimer’s disease—and providing the sole impetus for the establishment of the U.S. National Institute on Aging (NIA)—we are nowhere closer to understanding Alzheimer’s disease. Nor does anyone have any semblance of how to stop and cure the disease (for review see: Whitehouse, 2014; The, 2016; Garrett & Valle, 2016). Research remains disorganized, clinicians remain confused, and the public has become increasingly worried (for review see: Ballenger, 2017; Garrett & Valle, 2015). Although there are many potential alternate approaches to developing research guidelines on Alzheimer’s disease (for review see: Weuve, et al, 2015; Jessen, et al, 2014; Bennett, et al, 2015; Au, et al 2015; Snyder, et al, 2016; Garrett, 2017) we are back again to the original definition of the disease. Historical evidence informs us that it was wrong then, and scientific evidence informs us that it remains wrong today.

A century ago Alois Alzheimer published a case study where he identified plaques and tangles in the brain of a young woman of 51 years. This was not a new observation, nor was it unique. It was known that most people with dementia had the same brain malformations, including the majority with senile (relating to old age) dementia. This was such a non-event that Alzheimer’s initial attempt at publishing these observations in 1906 failed because it was not scientifically worthy, and it took a year for these observations to be published (Dahm, 2006). However, three years after this initial observation Emil Kraepelin—Alzheimer’s supervisor at the Munich clinic—included this observation of plaques and tangles in “young” patients as ‘Alzheimer’s disease’ in the eighth edition of his book Psychiatrie. Against the overwhelming evidence from the scientific community, a new disease was created.

We do not know Kraepelin’s motive for such hurried and ill-informed decision. However, the fact that his neurological clinic in Munich was in competition with the one in Prague likely played a role. The Prague clinic was headed by the much more accomplished Arnold Pick, who already had published more than 350 scientific papers and a textbook of neuropathology (Kertesz & Kalvach, 1996). More importantly, Arnold Pick already identified Pick's disease and the Pick bodies in dementia as a result of buildup of tau proteins (unknown at the time) in neurons defined as "Pick bodies.” In contrast Kraepelin and Alzheimer had no academic imprint in this area. Pick’s Prague clinic also included the highly accomplished neurologist Oskar Fischer who was the first to identify Amyloid Beta plaques which became known as Fisher Plaques. Both Fischer and Alzheimer had published observations that identified plaques and tangles, both using the same methodology of reduced silver staining technique developed in 1902 by Max Bielschowsky (Goedert, 2008). At a time, leading up to 1918, when the Weimar Republic was declared, ushering in a time of nationalism and emerging Nazi movement—the Jewish Fischer and Pick in concert with all other contemporary researchers, argued that Alzheimer’s disease was not a new disease. Politically Pick and Fischer were on the wrong side of emerging nationalism and anti-Semitic swell. It could be argued that politics outplayed science. By enshrining Alzheimer’s disease as a new disease—in contradiction to the overwhelming scientific evidence against a new disease—Kraepelin established a political aspect of Alzheimer’s disease and gained kudos for his newly established 2017 Munich clinic (now named Max Planck Institute for Psychiatry in Munich) to the detriment of the Prague clinic.

Fast forward in time, the second political event that falsely promoted the uniqueness of this disease came about with the creation of the U.S. National Institute on Aging. In 1974 Public Law 93-296 established the National Institute on Aging and in 1976 Robert (Bob) Butler was appointed its first director. The political theatre behind the scene revealed the true purpose of the NIA. Despite Butler’s interest in age inequity—having published a 1969 paper that defined “ageism” and then in 1976 he published a Pulitzer winning book Why Survive?: Being Old in America—Butler’s focus was always on neurological diseases. Butler confessed: ‘‘I decided that we had to make it [Alzheimer’s disease] a household word…And I call it the health politics of anguish.’’ (Fox, 1989; p. 82). By using Alzheimer’s disease to promote NIA’s mission, Alzheimer’s disease again become political. This involved a radical change. NIA’s founding members realized that politically, they needed something more than ‘diseases of older adults’ to validate their new institute to Congress. President Nixon at the time in rejecting the first proposal for the establishment of the NIA must have agreed with Congress that “we are not in the business of curing aging.”  Congress saw diseases of older adults as inevitable, one that required care rather than cure.  Dementia was also ill-defined, broad, and too diffuse a term to get Congress excited. In response and playing the “health politics of anguish” the founders of the NIA ingeniously focused on Alzheimer’s disease. Thanks to Kraepelin, Alzheimer’s disease provided a biomedical disease that can be approached as a biologically-determined disease—a real disease.

There was one problem with this approach: by definition, Alzheimer’s disease was primarily a disease of younger people and not a disease of older adults. There were very few patients suffering from real Alzheimer’s disease in the 1970s.  In fact, Robert Katzman himself in the 1976 article reports that cases were so few that “Precise epidemiological information [on Alzheimer’s disease] is not available…” (Katzman, 1976; p.378). It was becoming apparent that most patients with clinically defined senile dementia—onset of disease after 65 years—have very similar pathological changes in their brains as patients with Alzheimer's disease (Ballenger, 2006).  A century of criticism, arguing that dementia and Alzheimer’s disease are one and the same thing, was suddenly being recognized (Robertson, 1990). It became politically expedient now to ignore what Kraepelin and Alzheimer argued for and to admit that Alzheimer’s disease is not uniquely different from senile dementia. Katzman & Karasu (1975) already started eroding the distinction between dementia and Alzheimer’s disease and, as a result, the two constructs were merged. However, rather than changing the name of Alzheimer’s disease to senile dementia—because the establishment of the NIA relied on the banner of a neurological disease—the name Alzheimer's disease was retained and broadened significantly to include senile dementia (Katzman, 1976; Katzman & Bick, 2000). This proved extremely beneficial in the politics of anguish. An editorial by Robert Katzman in the April 1976 Archives of Neurology altered the balance (Katzman, 1976). In the short two-page article (plus references), Katzman made the argument for subsuming senile dementia under Alzheimer’s disease. It was not even peer-reviewed, again a political rather than a scientific discussion. Katzman’s political conjectures projected Alzheimer's disease as being the fourth or fifth most common cause of death in the United States. Overnight Alzheimer’s disease “became” a national public health issue. As Kraepelin “created” Alzheimer’s disease, Katzman “transformed” the disease into a public health menace.

Hubris plays a role again, Robert Katzman was not shy in acknowledging the importance of his usurping of senile dementia: "I think there's no question that that's my major contribution. Of the 115 papers I've written, that two-page editorial is clearly the most important." (Fox, 1989, p. 73). Now, the fate of Alzheimer’s disease became intricately woven with the promotion of the NIA. The creation of the NIA depended on Alzheimer’s disease gaining prominence and national attention. Without the banner of a disease, Congress was not going to fund research on aging. The ageist attitude was—and remains to this day—that aging is not important by itself. The founding fathers of the NIA knew that they needed constituents to bring the mission of the NIA to Congress, and that meant using Alzheimer’s disease as a lure. All they had to do was to persuade the general public that Alzheimer’s disease research was not only a national priority—as well as the NIA’s—but that it was their priority as well. The growth of locally-based Alzheimer’s associations was essential in order to bring public pressure on local and national representatives to support NIA’s mission.  This required a symbiotic relationship—one that has endured to this day. With all of this political activity, science was overlooked.

It took more than 80 years for a quasi-theory to be developed to explain Alzheimer’s disease. The Amyloid Cascade hypothesis (Hardy & Higgins 1992) proposed that the accumulation of two misfolded proteins—amyloid-Ī² peptide and tau tangles—in the brain was Alzheimer’s disease signature pathology (Karran, Mercken & De Strooper, 2011). Even by 1992, it was dead on arrival, existing evidence already refuted this hypothesis, and researchers working in the field knew this.

Deposition of amyloid (A4) protein deposits were (variably) present in 66% autopsies on adults over 65 years of age with progressive supranuclear palsy, 57% with Parkinson's disease, 40% with Huntington's chorea and in elderly patients with frontal lobe dementia (Mann & Jones,1990; Ross & Poirier, 2004). A signature biomarker that is shared by other diseases is not a signature but a rubber stamp. By 1990 researchers were arguing that the “Amyloid deposition in elderly persons may thus relate more to certain aspects of ageing and genetics than to AD [Alzheimer’s disease], per se.” (Mann & Jones, 1990; p. 68).  Two years later, despite these stark anomalies, the Amyloid Cascade hypothesis become hallowed knowledge and formed the basis for nearly all of the neurological work in Alzheimer’s disease—including the genetic creation of special (transgenic) mice whose brain is contaminated with amyloid plaques and tau tangles that form the basis for testing of all pharmacological interventions.

Repeating History
Based on the amyloid cascade hypothesis (Hardy and Higgins, 1992), active immunization against amyloid-Ī²42 peptide was proposed as a treatment. But so far, all types of ‘amyloid’ trials have failed.

In the active amyloid-Ī²42 immunization clinical trial by Elan Pharmaceuticals (AN1792), researchers were successful at clearing the amyloid-Ī²42 that formed the plaques. The immunization trials show that amyloid can be cleared from the brain. The clearance of visible plaques was seen as a revolution, the “holy grail” that the new Framework is resurrecting. The problem is that cognition was not improved (Hock et al., 2003; Bayer et al., 2005; Gilman et al., 2005). In fact, longer term follow-up revealed continuing cognitive decline despite removal of plaques (Holmes et al., 2008). The argument is that it is possible that the damage has already been done and therefore the clearing of the plaques is inconsequential to the residue of the disease.

Another approach was related to inflammation response. There was observational evidence that inflammation is part of the disease process. The discovery that patients with rheumatoid arthritics who regularly consume non-steroid anti-inflammatory drugs (NSAIDs), had lower rates of Alzheimer’s disease (e.g., Andersen, et al, 1995). However, the anti-inflammatory drug Rflurbuprofen trial conducted by Myriad Genetics was stopped. Although stage two showed some promise, the outcomes in stage three proved non-significant. It was not clear whether the concentration was sufficient (800 mg) and whether the effects of the drug were too diffuse and non-specific. It is not possible to interpret the outcome of the trial in any useful way. More recent studies with NSAIDs on reducing the incidence of Alzheimer’s disease have proven inconclusive (Wang, et al, 2015; Miguel-Ɓlvarez et al, 2015.) Best interpretation is that a daily dose of generic ibuprofen reduces the likelihood of Alzheimer’s disease. These studies did however leave one possible interpretation. That the lack of outcomes could be due to the disease already being present and therefore the intervention could not prevent it. Again, the argument being proposed is that there is a need to catch the disease much earlier (McGeer, Rogers & McGeer, 2016.) The Framework complies with this hypothesis. But there is a problem in logic.

If by removing amyloid-Ī² in patients resulted in poorer performance on cognitive testing in human trials (Gilman et al, 2005; Boche et al, 2010; Dodart et al, 2002) then the plaques cannot be the disease (Iqbal, Liu & Gong, 2014).  Therefore, if one of the signature disease of Alzheimer’s disease is found not to cause Alzheimer’s disease then something else must cause the dementing features that we observe.  Boche et al (2010) concludes that; “However, the continuing progression of cognitive decline in AD patients after Abeta immunisation [plaques] may be explained by its lack of apparent effect on tangles [tau].” (p.13). The results are clear, the amyloid-Ī²42 are precursors to the real disease which is the tau tangles. It could be that there are unknown, or hidden precursors. But the Framework does not address the possibility that Alzheimer’s disease is caused by biomarkers that we perhaps have not yet identified or know about.

The Tau Influence
Given these setbacks, the only way that the Amyloid Cascade hypothesis can survive is through two interpretations. One is that we need to treat the disease at earlier pre-clinical stage, and secondly to develop safer immunization of amyloid-Ī²42 since this seems to be the precursors to the tau tangles which might be the cause of the clinical disease. But this strategy has not fared well in the past. In 2018, Stefano Cappa with the Institute for Advanced Studies, Pavia Italy remarked that the competing “tau hypothesis” shares most of the conceptual assumptions of the amyloid approach—the idea that the development of Alzheimer’s disease could be stopped or delayed by interfering with the biology, in this case the formation of neurofibrillary tangles—pathologic Tau (Cappa, 2018).

Despite reservations, resources have been diverted to the next big thing—stopping Tau from becoming a problem in the brain. There are four ways this protein becomes toxic and so far, there are attempts to limit two of these (phosphorylation and glycosylation.) Although these are showing positive results in animal studies (Lim et al., 2000) and in reducing risk of Alzheimer’s disease (Szekely et al., 2004), so far, the results have been insignificant and diffuse (Li, Kaida-Yip &  Zabel, 2018).

While there are treatments that attempt to immunize, and therefore stop the formation of tau, these therapies have similarly shown some success at clearing the tau but without the desired clinical outcome. It seems that the theory is wrong from the start. The biology—tangles and tau as the neuropathology—might contribute, moderate and/or mediate the disease, but it is unlikely to be the disease itself. However, reliance by relying on the objectives of the Framework’s stated ambition of clearing the amyloid-Ī²42 and tau tangles, then we have succeeded: Mission Accomplished. Especially if we remove the clinical outcome by ignoring the observation that individuals’ dementing behavior does not improve (Boche et al, 2010).

But judging success on neurology and ignoring clinical evidence is superficial. If clearing the amyloid-Ī²42 and tau tangles results in the patient retaining the clinical disease i.e., suffering from memory disorders, personality changes, and impaired reasoning., then we have failed. The public does not want clean brains they want the “abnormal” behavior to go away. Any approach that ignores these realities of success is doomed even if the objectives of the Framework are successful.

The clinical aspect of the disease deserves attention. The Framework specifies that; “…[a] person has an AD [Alzheimer’s disease] biomarker profile, we cannot know if the cognitive deficit is attributable to AD alone or to other potential comorbidities in addition…different cognitive stages may be present in the population among people with the same biomarker profile” (Jack et al, 2018; p.546) Not only does the Framework not address the clinical aspect, but it argues against the role of biomarkers in the clinical expression of the disease.

Following the lead of Bruno Dubois with the University Pierre & Marie Curie, Paris—and colleagues with the International Working Group (IWG) and also with the NIA-AA—there already was a movement to improve upon the existing Guidelines of 2011 (Jack et al 2011) and improving upon the clinical diagnosis of Alzheimer’s disease (DuBois et al, 2014). This was the right approach. The initial Guidelines, although not without criticism (e.g. Weuve et al, 2015; Garrett & Valle, 2014), proposed that Alzheimer’s disease progresses on a continuum with three stages (Jack et al., 2011). The first is an early, pre-clinical stage with no symptoms (Sperling et al., 2011), followed by a middle stage of mild cognitive impairment (MCI) (Albert et al., 2011), followed by a final stage of Alzheimer’s dementia (McKhann et al., 2011). An additional update focuses on the criteria for identifying Alzheimer’s related changes at autopsy (Hyman et al., 2012). These further improvements on the original guidelines were concerned with the clinical application of their work. Importantly they were aware of how Alzheimer’s disease can have atypical forms, mixed diseases and can have a preclinical presence.

By ignoring all of these aspects of the disease, ignoring the scientific literature that negate the simplicity of the Amyloid Cascade hypothesis and the similarly ill-fated tau-cascade hypothesis, and focusing purely on the biology—regardless of the clinical aspects—the Framework is attempting not just to define a new diagnosis of Alzheimer’s disease it is trying to reengineer how we define diseases.

Nosology
How we classify diseases have always relied on their clinical expression except for now. In 2008 the National Institute of Mental Health (NIMH) introduced Research Domain Criteria (RDoC), a new classification of diseases—nosology. It was especially promoted by the NIMH then director Thomas Insel, who has now migrated to Google Life Sciences which in the Google empire has become a full-fledged member of Mountain View's Alphabet Inc., and taken on a new name: Verily, a for profit health company.

The RDoC baptism in 2013 coincided with the publication of the DSM-5— Diagnostic and Statistical Manual of Mental Disorders the definitive reference for diagnosing psychiatric disease sponsored by the American Psychiatric Association—which itself heralded a radical diagnostic departure is moving towards more dimensionality of disease (no longer binary), relying on more biological indicators and an emphasis on pharmacological outcomes. The implicit assumption in DSM-5 and explicitly stated in RDoC is that behavioral/mental/clinical disorders are manifestations of biological/neurological disorders. Bad behavior is nothing more than biological expressions. Fixing the biology will fix the problem. Thomas Insel himself argued that the explicit emphasis of RDoC is to “yield new and better targets for treatment.” (Insel, 2013)   While demoting the importance of understanding the disease, it elevates the search for a cure. An illogical approach. Underwhelming the scientific method in favor of a panacea, one that accommodates an economic imperative.

A backlash of criticism ensued (e.g., Nemeroff, Weinberger & Rutter, 2013; Peterson, 2015; Weinberger, Glick & Klein, 2015) but despite evidence against this approach, RDoC gained legitimacy. RDoC’s biological determinism was promoted by the success of how easy it was for the public and scientists to believe that Alzheimer’s disease was determined by a simple disease, a biological malfunction. The history of Alzheimer’s disease laid the foundation for a new way of biological determinism that has not been seen since the height of the eugenics movement in 1923 when the American Eugenics Society was founded. But this emphasis on biology is unfounded. There is no evidence that biology exclusively determines Alzheimer’s disease or any other mental disorders.

Eugenics Versus Science
In May 2016, in a short eight-page report in Nature Biotechnology, Rong Chen, Stephen Friend and Eric Schadt from the Icahn School of Medicine at Mount Sinai, New York, and their colleagues reversed our idea about genetic determinism. This small revolution proved to be radical because by association, this also unhinges biological determinism—the belief that biology determines all your traits (Chen, et al, 2016).

What they did is to apply scientific method to examining commonly held beliefs about disease. Usually genetic investigations focus on a group with a disease and then identifying genes that are different in this group from the rest of the (control) population. By comparing this group with a control group, they can single-out a gene that “caused” this difference. Sometimes geneticists hit lucky and find only one gene that is different between the two groups. In such circumstances this single gene follows Mendelian laws in how it affects people. Mendelian laws are named after the monk Gregor Johann Mendel who between 1856 and 1863 discovered the mathematics of heritability. Using this methodology, scientists have subsequently identified 584 Mendelian diseases: where one gene causes a specific disease. For the first time the validity of this assumption was being tested. The results were unexpected and revolutionary.

Rong Chen and his colleagues screened for 874 genes among 589,306 individuals. They identified 15,597 individuals who had genes for debilitating diseases but they did not express the disease—they were genetically infected but did not show it. After rigorous elimination of candidates for various technical and theoretical reasons, 13 individuals had genetic disorders for: cystic fibrosis, Smith-Lemli-Opitz syndrome, familial dysautonomia, epidermolysis bullosa simplex, Pfeiffer syndrome, autoimmune polyendocrinopathy syndrome, acampomelic campomelic dysplasia and atelosteogenesis. For over fifty years it was believed throughout the scientific community that having one of these genes results in a debilitating disease. But for these lucky 13 adults they were completely normal. They did not express the disease. This single paper heralds the death of biological determinism. What this informs us is that even Mendelian disease are mediated or moderated by something other than genetics or biology. We know very little about what can moderate and mediate this process.

The Framework usurps the RDoC mission. But despite the change in name, the aim similarly dictates biomarkers as diseases. But science contradicts this assumption. The NIA-AA Framework relies exclusively on biological markers even though “None of the biomarkers are as sensitive as direct examination of tissue at autopsy.” (Jack, et al, 2018; p.544) The reliability of the tools we have to measure these biomarkers are questionable; “a negative amyloid PET scan should not be equated with the complete absence of Ab [amyloid-Ī²42] in the brain or even with absent or sparse neuritic plaques [tau tangles]…pathologic tau that can be present in the brain below the in vivo tau PET detectable threshold is unknown at this time.” (Jack, et al, 2018; p.544). The tools we have are unreliable, but even more worrisome, they lack of validity—they are useless. We have to judge how sensible choosing neurological degradation to define degradation when “the number of neurons or neuronal processes that must be lost to detect atrophy on MRI or hypometabolism on FDG PET is not known.” (Jack, et al, 2018; p. 544). These anomalies must have been identified in the Framework to placate critics, but they succeed in highlighting the lack of robustness of the theory they are proposing. Even if we accept that this aim is to focus on cure, how reliable is this approach to help cure Alzheimer’s disease when these biomarkers are known to relate (cause?) other diseases.

The AT(N) biomarkers are not an exclusive signature of Alzheimer’s disease alone.  “In any individual, the proportion of observed neurodegeneration/injury that can be attributed to AD [Alzheimer’s disease] versus other possible comorbid conditions (most of which have no extant biomarker) is unknown.” (Jack, et al, 2018; p. 543). These admissions pose serious scientific flaws that expose this Framework to failure. There is also no connection between these biomarkers as the authors confess: “The AT(N) biomarker system does not imply a specific order of events nor does it imply causality.” (Jack, et al, 2018; p. 541.) And even though the authors refrain from using the clinical expression, their only means of validating the disease is through its clinical expression: “The rate of cognitive decline is significantly greater for cognitively impaired and CU [cognitively unimpaired] individuals who have abnormalities in both an amyloid biomarker and a second biomarker type (which could be CSF T-tau or P-tau, atrophy, or hypometabolism) in comparison to individuals who have neither or only one of these biomarker abnormalities.” (Jack, et al, 2018; p.541-2). There is not one study that can prove that “…biomarkers predict greater likelihood of and more rapid cognitive decline” (Jack, et al, 2018; p.542). It is likely, but the science has not been done, and science cannot be prejudged.

Ignoring Science
The disclaimer is that this framework is “…for research purposes only…”  Defining a research framework through an international publication under the auspices of a U.S. National Institutes is unnecessary. A research directive can easily have been issued through a Request for Proposal directive. As with the 2011 guidelines, again issued by the NIA-AA, the effect was that the then newly proposed clinical continuum—pre-clinical/Mild Cognitive Impairment/Alzheimer’s disease—was adopted by clinicians throughout. Given the research importance, the Framework will similarly be (haphazardly and unevenly) adopted across the clinical field. Such duplicity remains worrisome. A truly research framework would approach it through scientific methods, not through self-serving selection of cherry-picked facts designed to look progressive. Especially one that serves the pharmacological industry.

A scientific study would establish the follow: What are the correlates of dementia (both biological and clinical.) Other "mis-folded" proteins are present in brains, some 34 proteins can mis-fold, why focus on just two? If Alzheimer's disease is an amyloid problem why not look at this under amyloidosis instead of separately?  Why are some mis-folded proteins useful? A longitudinal study of chemical changes in the brain, particular attention to the effect of physical and psychological trauma and the brain. This establishes all the parameters. A theory must at least include all of these parameters. If there is a focus on just two biomarkers, the amyloid-Ī²42 and the tau neuritic tangles then how many people (of all ages) have these biomarkers, what is the tipping point and what is the cut-off point where it is clinically expressed through dementia (or other clinical disease)?  You cannot do this science without the clinical aspect of the disease.

But the main failure of the Framework is not its lack of scientific rigor, it is its lack of scientific insight. The brain is the most complex entity in the universe, no other system or organ is as complex. Valid competing explanations for dementia invariably treat the brain as a complex system, and therefore any disease is expressed through the breakdown of complex systems. For example, in older people there are changes in resilience, reduction in body temperature, hormone changes (especially for women) all of which affect the blood-brain-barrier and other biological systems that protect the brain from infections. With reduced resilience, the brain receives an onslaught of bacterial, fungal, viral, metal, and other invasions that the brain experiences difficulty in coping. The plaques and the tangles in this scenario are responses to this attack. The frameworks exclusive focus on these biomarkers does not elucidate the many different dynamic processes of infection. Science first needs a theory. Observations are not made in a vacuum.

Science is a method, based on theory. There is no such thing as scientific fact, only observations obtained through scientific method. A theory accomplishes three primary things. First it summarizes all existing information, without ignoring anomalies. It explains all that is observed. Secondly a theory predicts. Thirdly a theory generates hypotheses that are open to testing and refutation. We can test a theory through its many parts. During this stage of testing, the method of science is to test the smallest number of variables against the most discreet outcome. This stage relies on a good methodology and accurate statistics. Most science fails here.

Science is reliant on constant replication in order to ascertain the relationship that we are observing is indeed real (i.e. true). The likelihood that a research finding is indeed true depends on three indicators: the prior probability of it being true (before doing the study), the statistical power of the study, and the level of statistical significance (Wacholder et al, 2004; Risch, 2000). Because most studies do not follow these requirements, focusing instead on statistical significance alone, Ioannidis argues most current published research findings are false (Ioannidis, 2005). We are creating false science and building upon an edifice of falsehoods.

This level of unawareness is further fueled by attempts to find a cure before understanding what we are trying to cure. Such applied science, however noble, is not science. Science is a method used to understand a phenomenon. It is not predetermined. With the new target to develop a cure for Alzheimer’s disease by 2025 (Cummings et al 2016) we continue to ignore “—incomplete understanding of AD pathogenesis, the multifactorial etiology and complex pathophysiology of the disease, the slowly progressive nature of AD, and the high level of comorbidity occurring in the elderly population.” (Sugino et al 2015). We are kicking the can down the road. We will find ourselves in the same spot in a century from today and we will be reading the same kind of criticism as we are here.

Conclusion
Arnold Pick saw dementia as “. . . a mosaic of localized partial dementias. . .” (Tilney, 1919, p. 35), Alzheimer’s disease is likely caused by a mosaic that includes: viral (HIV/AIDS, herpes simplex virus type I, varicella zoster virus, cytomegalovirus, Epstein-Barr virus), bacteria (syphilis and lyme-disease/borrelia), parasites (toxoplasmosis, cryptococcosis and neurocysticercosis), fungi (Candida glabrata), infections (possibly prions), and vascular (stroke, multiple-infarct dementia, hydrocephalus, injury and brain tumors)(Garrett & Valle, 2014).

There are processes that promote and delay the infection and the spread of infection. Primarily the Blood-Brain-Barrier (e.g., Deane, et al 2009), inflammation (e.g., Lee, et al 2000), vascular (e.g., DiMarco, et al, 2015), White Matter (e.g., Serrano-Pozo, et al, 2011) and many other dynamic processing in the brain. Such models already exist (e.g., among many others see Schelke, et al 2018).

The brain is complex and science is nowhere close to understanding the mechanics let alone curing specific diseases. Shortchanging science in order to get to a quick fix is demeaning to scientists and defrauds humanity.  We will end up in the same position a hundred years from now.

We end with a warning that was predicted more than 100 years ago. Such consequences were predicted in 1911 by Gaetano Perusini, one of the brilliant researchers working with Alois Alzheimer, when he wrote: “[scientists] who amuse themselves with anatomically localizing the location of conscience, the will and related matters, would find a good playground, in which the tangles, for instance, might offer the most clear-cut explanation for the disorientation observed in the senile demented patient…” (Perusini, 1910, p 144).

Older adults have truly become a playground for a new wave of eugenics. Ignoring the sociological, psychological and social context of the disease. Shame on the National Institute on Aging.


 © USA Copyrighted 2018 Mario D. Garrett


Note:
A= Biomarkers of Ab plaques in the cortex of the brain. Measured by injecting a radioactive material—ligand—that attaches to the plaques and then imaged using Positron-Emission Tomography-PET. Or measured by low Ab42 in the cerebrospinal fluid (CSF).

T= Biomarkers of fibrillar tau. Measured by injecting a radioactive material—ligand—that attaches to the tau and then imaged using Positron-Emission Tomography-PET. Or measured by elevated phosphorylated tau (P-tau) in the cerebrospinal fluid (CSF).

--> N=Biomarkers of neurodegeneration or neuronal injury. Measured by elevated phosphorylated tau (P-tau) in the cerebrospinal fluid (CSF). Measuring metabolism in the brain by injecting Fluorodeoxyglucose (FDG) which is a radioactive chemical that is taken up by cells as if it is glucose and then measuring activity with Positron-Emission Tomography-PET. Hypometabolism is not defined.  In additional the measure include atrophy as measured by Magnetic Resonance Imaging (MRI). Atrophy is not defined.



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