Reviewing What is Known of the Aging of Stem Cells

One of the important contributions to the aging process is a progressive reduction in stem cell activity. The majority of tissues in the body are in a constant process of turnover. The somatic cells making up the bulk of all tissues reach the Hayflick limit on replication and self-destruct, and are replaced by new cells generated by tissue-specific stem cell populations. With age, these stem cells spend ever more time quiescent, and thus the supply of new somatic cells declines, causing tissues and organs to deteriorate and ultimately fail. This loss of stem cell support is thought to have evolved as part of a balance between risk of death by cancer versus risk of death through failing tissues. As cells become more damaged with age, the risk of cancer with cell activity increases. Lower cells of stem cell activity dampen that risk somewhat, at the cost of a slower decline into frailty and disease. Still, restoration of youthful stem cell activity is one necessary component of any future toolkit of rejuvenation therapies. To the degree that this raises cancer risk, that is an additional challenge to overcome along the way, not a reason to stand back and do nothing.

Aging is an unavoidable physiological consequence of the living animals. Mammalian aging is mediated by the complex cellular and organismal processes, driven by diverse acquired and genetic factors. Aging is among the greatest known risk factors for most human diseases, and of roughly 150,000 people who die each day across the globe, about two thirds die from age-related causes. In the modern era, one of the emerging fields in medicine is stem cell research, as stem cells have the remarkable potential for use to treat a wide range of diseases. Stem cells are undifferentiated pluripotent cells that can give rise to all tissue types and serve as a sort of internal repair system. Until the recent advance in development of induced pluripotent stem cells (iPSCs), scientists primarily worked with two kinds of pluripotent stem cells from animals and humans: embryonic stem cells, which are isolated from the inner cell mass of blastocysts, and non-embryonic "somatic" or "adult" stem cells, which are found in various tissues.

Although stem cell science promises to offer revolutionary new ways of treating diseases, it is identified that aging affects the ability of stem (and progenitor) cells to function properly, which ultimately can lead to cell death (apoptosis), senescence (loss of a cell's power of division and growth), or loss of regenerative potential. Aging may also shift gene functions, as reported for some genes, such as p53 and mammalian target of rapamycin (mTOR), which are beneficial in early life, but becomes detrimental later in life. In this regard, a novel theory, namely the "stem cell theory of aging", has been formulated, and it assumes that inability of various types of pluripotent stem cells to continue to replenish the tissues of an organism with sufficient numbers of appropriate functional differentiated cell types capable of maintaining that tissue's (or organ's) original function is in large part responsible for the aging process.

In addition, aging also compromises the therapeutic potentials of stem cells, including cells isolated from aged individuals or cells that had been cultured in vitro. Nevertheless, in either case, understanding the molecular mechanism involved in aging and deterioration of stem cell function is crucial in developing effective new therapies for aging- as well as stem cell malfunction-related diseases. In fact, given the importance of the aging-associated diseases, scientists have developed a keen interest in understanding the aging process as well as attempting to define the role of dysfunctional stem cells in the aging process.

From the various advances in stem cell research, it is clear that we grow old partly because our stem cells grow old with us. The functions of aged stem cells become impaired as the result of cell-intrinsic pathways and surrounding environmental changes. With the sharp rise in the aging-associated diseases, the need for effective regenerative medicine strategies for the aged is more important than ever. Fortunately, rapid advances in stem cell and regenerative medicine technologies continue to provide us with a better understanding of the diseases that allows us to develop more effective therapies and diagnostic technologies to better treat aged patients.

Link: https://dx.doi.org/1...93/WJEM.v7.i1.1

View the full article at FightAging

I am not a scientist and am not trying to stir up a controversy. However, the doctors that undertook my stem cell treatment told me that stem cells don't age, beyond the differentiation process that takes place during early development. But that fewer of them are released versus those kept in reserve. Maybe this is part of our genetically programmed obsolescence, or perhaps because for a long time lifespans were much shorter and our genome hasn't yet adapted to keeping us healthy during decades that used to be extremely rare for our species? In any case they say that the stem cells are just at potent when older, however the needed repairs are far greater, making their action insufficient without adding stem cells by infusion. FWIW

To me, aging is like a building on fire, and stem cells are workers fixing the plumbing and electrical system as the building burns. Totally useless until a way is found to stop the rest of the cells from aging.

Stem cells will never live up to to the hype of the 90s and 2000s.

To me, aging is like a building on fire, and stem cells are workers fixing the plumbing and electrical system as the building burns. Totally useless until a way is found to stop the rest of the cells from aging.

Stem cells will never live up to to the hype of the 90s and 2000s.

 

I dunno about that, cell turnover would be a really helpful thing so long as there are plenty more stem cells to go around.

I need some advice on this. I think a combination of stem cells and Rapamycin might be ideal. As well as finding things to correct circuits in mental health

The 1st 2 to be cycled of course. This could be the answer. Stem cell precursors I mean stuff like Icarian and apigenin similar to Turnbuckle's suggestions. Then 1 day a week when a Rapamycin or 2 is taken to create autopaghy. The rest of the time grow new cells. That might just do it. What do you guys think?