◉ The Rational for Young Plasma as an Anti-Aging Intervention

A large number of age regressive treatment modalities are currently in development. Most hold the promise of partial rejuvenation, defined by the reduction of epigenetic clocks, improved physical/biometric outcomes and increased healthspan and lifespans. None of these promising modalities are currently available with the exception of one; Young Plasma.

Young plasma is the source from which many therapeutic modalities are being derived, with each modality essentially acting as a derivative containing a single signaling source. A large subset of the treatments currently in development are individually isolated plasma fractions, as indicated in table-1 below. This fact emphasizes the complexity and compound nature of signals required to effectively regress the aging process. Young plasma contains all of the thousands of signaling molecules, proteins, lipids, growth factors, hormones, and exosomes previously identified as having youthful or anti-aging properties, underscoring the necessity of a broad and multifaceted approach to manipulate cellular chrono-epigenetic regulation systems (CERS) for effective rejuvenation.

Tony Wyss-Coray’s group previously identified 529 proteins that had been reported by multiple studies derived from 4263 healthy individuals with an age range of 18–95 years. These proteins changed their expression level with age in human plasma [ XX2 ] . A literature search revealed that at least 64 of these 529 proteins are capable of regulating life span in an animal models. They also determined that: 75.84% (361) of all proteins associated with aging (529 total targeted proteins) increased expression with age while only 24.16% (115) are associated with a decreased expression. Wyss-Coray has referred to these age signaling molecules as Chronokines. Chrono indicating time and kines indicating signaling.

Importantely young plasma is rich in multiple youthful chronokines signaling molecules—proteins, lipids, growth factors, hormones, and exosomes—all recognized for their anti-aging properties. This rich composition has shown promising therapeutic potential when administered to older individuals, significantly reducing markers of biological and epigenetic aging while enhancing cognitive function and tissue repair. Grifols, one of several giant plasma processing companies, leverages these insights through it wholly own biotech subsidiary; Alkahest. Alkahest development focus is on isolating and developing sterilized plasma fractions (individual molecules isolated from plasma) that target aging and disease.  For the reasons previously described the therapeutic benefit from these single molecules is unlikely to create the long term, systemic aging benefits of young plasma.

The interaction between the youthful and aging chronokines represents a complex but never less, numerical war: each youthful signal works to cancel or neutralize the effects of “old” aging signals. As the CERS introduction to this page indicates, it is not this direct, but the analogy still holds. This dynamic can be likened to a battle between two armies: the detrimental aging signals from old plasma, like an advancing force of decline, can be counteracted by the youthful signals from young plasma, which marshal forces of regeneration and repair to reclaim lost ground in the ongoing war against aging. The location of the front line as measured by epigenetic and proteomic clocks plays a critical role in determining the overall health and aging trajectory of an organism. As you age, aging signaling chronokines increase. This makes diluting the plasma a partial, but incomplete interventional strategy. Increasing the youthful signaling chronokines by infusing young plasma provides younger, healthier troops to enter this battle leading to providing numerical superiority on the  battlefield of these warring chronokines.  

The table of signaling molecules provided below is a very small, generic list of a very large inventory of age controlling signaling agents found within plasma. For a detailed proteomic inventory see references: [13] and The 2023 Report on the Human Proteome from the HUPO Human Proteome Project. The Human Proteome Project Organization maintains a website that provides the results of research designed to identify all of the proteins involved in development, diseases, immunity and aging. They have also produced the excellent introductory video (embedded above) describing proteomics.

Table-1

Partial Inventory of the Molecular and Signaling Components of Human Plasma

1. Proteins:

- Albumin: Maintains oncotic pressure and transports substances.

- Globulins: Includes immunoglobulins, transport proteins, and clotting factors.

- Fibrinogen: Essential for blood clotting.

2. Electrolytes:

- Sodium (Na+), Potassium (K+), Chloride (Cl-), Calcium (Ca2+), Magnesium (Mg2+): Regulate osmotic balance and nerve/muscle function.

3. Nutrients:

- Glucose: Primary energy source.

- Amino Acids: Building blocks of proteins.

- Lipids: Including cholesterol and triglycerides.

4. Hormones:

- Insulin, Glucagon, Cortisol, Thyroid Hormones, Sex Specific Hormones: Regulate metabolism, growth, and reproduction.

5. Growth Factors:

- Epidermal Growth Factor (EGF), Platelet-Derived Growth Factor (PDGF), Transforming Growth Factor-Beta (TGF-β), Insulin-like Growth Factors (IGFs), Vascular Endothelial Growth Factor (VEGF): Regulate cell growth, proliferation, differentiation, and survival.

6. Waste Products:

- Urea, Creatinine, Bilirubin: Byproducts of metabolism, excreted by kidneys/liver.

7. Gases:

- Oxygen (O2), Carbon Dioxide (CO2), Nitric Oxide (NO): Transported and exchanged in blood, with nitric oxide playing a key role in vasodilation and cardiovascular regulation.

8. Extracellular Vesicles:

- Exosomes, Microvesicles: Membrane-bound vesicles released by cells, containing various biomolecules such as proteins, lipids, and nucleic acids. Exosomes play roles in intercellular communication, immune regulation, and disease pathogenesis.

9. Other Components:

- Enzymes and Coenzymes: Catalyze biochemical reactions.

- Cytokines: Regulatory proteins involved in immune responses.

- Vitamins and Minerals: Essential micronutrients.

10. Water 90% by volume

For a much more complete overview of the proteome of human plasma see:

Additional, therapeutic age-regressive modalities exist and they include dilution utilizing therapeutic plasma exchange (TPE).  Some dilution naturally occurs as a consequence of infusing young plasma and TPE can be an additive process when combine with young plasma.  If as indicated in the Wyss-Cory paper above, three times as many age associated/controlling components of the proteome increase (75%) as aging progresses and (25%) decrease, it would be a reasonable conclusion that a protocol incorporating a 50% dilution of all plasma proteins, would result in a net positive impact on aging and correspondingly disease. [23] It would appear obvious that modulating the increasing signals to a lower level and increasing the declining signals to a higher percentage would be an effective interventional stratgie. One study by the Conboys demonstrated the benefits of this type of intervention. [11]

Reprogramming induced rejuvenation utilizes transcription factors to alter the epigenetic landscape and may be the most effective age regressive therapeutic in development, but it is still in development and not likely to become clinically or commercially available for 3 to 5 years.  

Exosomes derived from young animals like pigs, are in developed by Harold Katcher and others, also appear to be highly effective at reducing epigenetic clocks. Exosomes are a single type of Extracellular vesicles (EVs), found in plasma and as such are also another  component of yFFP.  One note about exosomes is they are expressed by multiple cell types throughout the body and as their sources are diverse so are the signaling molecules and mRNA’s that get encapsulated in the bi-lipid envelopes.[]

◉ History of Heterochronic parabiosis and the discovery of aging plasticity

From Myth to Modern Science:

Discovering the Rejuvenating Power of Young Blood

Throughout history, the quest for immortality has been a persistent theme in human culture, often intertwined with the mystical allure of young blood. Ancient civilizations (circa 3000 BCE - 476 CE) revered blood, especially from the young, for its supposed life-giving properties. This concept found its way into various cultures and epochs, most notably through the enduring legends of vampires. From ancient times to the present, these tales depicted immortality achieved through blood consumption, reflecting humanity's deep-seated fascination with and fear of mortality.

During the Medieval and Renaissance periods (circa 476 - 17th century), this fascination took a more practical turn. Alchemists and early physicians speculated on the restorative properties of blood, a pursuit that mirrored the broader search for the elixir of life. Although steeped in mysticism and often lacking empirical evidence, these early explorations hinted at a profound truth that modern science is only now beginning to uncover.

In an ironic twist of fate, contemporary scientific research has started to validate what these ancient myths and practices have long suggested. Studies in parabiosis, particularly involving the circulatory systems of young and old mice, have revealed that factors present in young blood can indeed rejuvenate older organisms. This groundbreaking research suggests that certain elements in young blood , primarily exosomes at this juncture, have the potential to reverse or slow down some aspects of the aging process.

This convergence of myth and science is a remarkable testament to the intuitive understanding of our ancestors. It underscores a fascinating aspect of human knowledge: myths, often dismissed as mere fabrications, can unexpectedly contain kernels of valid scientific truth. In the case of the rejuvenating power of young blood, a concept once shrouded in legend and mystique, we find a striking example of how ancient beliefs and modern scientific discoveries can align, revealing insights that have been both fostered and discounted for centuries.

Parabiosis: The first Clues to Aging Plasticity

Humanity's enduring quest to conquer diseases, slow or reverse aging, and evade death has led to significant scientific breakthroughs. A notable milestone was achieved over a century ago with the introduction of heterochronic parabiosis, a novel technique that combines the vascular systems of young and old animals. (see illustration on right). 

The first recorded experiment of parabiosis dates back to 1864 by the French physiologist Paul Bert. Bert's doctoral thesis, in which he described the concept of combining the vascular systems of two animals: titled "Sur la Greffe Animale." In this thesis, Bert detailed his experiments on albino rats, where he sutured the skin of two rats at their flanks and observed that intravenously administered fluids passed from the circulation of one animal into the bloodstream of its attached partner. [1]

A pioneering parabiosis study by Clive McCay at Cornell University in 1957 [2], joined the circulatory systems of young and old rats, providing early evidence of the rejuvenating potential of young blood, observed through improvements in cartilage health and other age-related conditions in older rats. In 1972, Ludwig and Elashoff, at the University of California studied the lifespans of old, young rat pairs. Older partners conjoined to young rats lived for four to five months longer than controls, suggesting for the first time that the circulation of young blood might affect longevity.[3] This provided the first documented study resulting in the extension of life in an old animal as a result of exposure to a young animals blood. 

In 2005, researchers Irena Conboy and Thomas Rando reinvigorated interest in parabiosis, exploring in greater depth the molecular and cellular mechanisms through which young blood might rejuvenate older organisms and its potential implications for human aging and age-related diseases.[4] This ignited a quest to identify exactly what the signaling molecules were within the blood that imparted the age regression benefits. 

Heterochronic parabiosis has been instrumental in uncovering many of the secrets of aging. It disclosed the potential of young mammals' plasma, which contains age signaling molecules. Youthful signals are referred to here a Type 1 Chronokine Profiles (T1CP). Aged or old signals are identified as Type 2 Chronokine Profiles (T2CP). The levels of each age-defining molecule present in the plasma of younger organisms, capable of imparting anti-aging effects when introduced in sufficient quantities into older animals, essentially represent a youthful biochemical signature that defines and aligns the cells of the older organism to the same approximate age as the donor. 

Parabiotic studies are continuing to demonstrate multiple benefits of pairing young and old animals, particularly overloading the system with youthful, T1CP signals, overridingand/or suppressing T2CP aging signals. [13] These benefits include enhanced muscle and tissue regeneration, mirroring younger counterparts, marked by epigenetic clock alterations. Cognitive functions, including memory and learning, improve, while signs of cardiac aging, such as heart hypertrophy, are reduced. Liver function is notably better, and stem cell revitalization occurs, aiding in tissue maintenance and repair. There's a significant reduction in age-related biomarkers, suggesting a systemic reversal of aging, including dramatic reductions in multiple epigenetic clocks. Additionally, age-related diseases, including degenerative conditions, show signs of alleviation or resolution. Finally, an increase in lifespan has been observed in older animals, attributed to the rejuvenating effects of young blood.

As we indicated, these studies are continuing today with the most recent one [Biological Age Reduction and Lifespan Extension Upon Youthful Circulation Exposure;  Zang et al., 2023] demonstrating that the two most effective age-regression targets: epigenetic and transcriptome remodeling, are both modulated in a positive way resulting in the extension of lifespan and health'span.  

Another important insight was again accomplished by the Conboy’s when they demonstrated that simply diluting the plasma of older (T2CP) animals with sterile saline provided significant benefits in multiple tissue types, improved memory and cognition and reduced inflammation. This suggests that a mere reduction in the T2CP signals is sufficient to improve the health of an individual.  An approved medical procedure, therapeutic plasma exchange or plasmapheresis is currently available to achieve this type of plasma dilution. A large human clinical trial is currently being conducted by Dobri D. Kiprov, MD HP (ASCP) In collaboration with Irena Conboy’s group to determine the impact on aging and disease from the dilution of the plasma by plasmapheresis.[16] 

In 2020 it was determined by Harold Katcher [19] that fractions within the plasma as opposed to the blood cells contained the molecular signaling agents responsible for these biological, age signaling benefits. Although identified in his first patent[31], it was not until a 2023 publication that the active molecules imparting age regressive benefits were definitively identified as a specific subtype of extracellular vesicles; exosomes.[36].hormones and exosomes, previously identified as having anti-aging properties.

  ◉ Human Clinical results of yFFP in a wide number of indications including aging

By Disease Indication:

Young plasma transfusion has been explored in various clinical contexts, primarily targeting age-related diseases and rejuvenation effects.

Arthritis (Degenerative )(Knee pain)

Alzheimer’s Disease (AD)

Alkahest, a biotechnology company, conducted several clinical trials using plasma fractions from young donors to treat Alzheimer's disease. Early phase trials suggested some improvements in biomarkers and cognitive function, but results were preliminary and required further validation.

A small trial at Stanford University explored the safety and feasibility of administering young plasma to patients with mild to moderate Alzheimer's disease. Initial results indicated some improvement in functional ability, but the trial was small and lacked a control group, limiting the conclusiveness of the findings.

Antidotially one individual had a dramatica recovery of long term memory.

[2019] Safety, Tolerability, and Feasibility of Young Plasma Infusion in the Plasma for Alzheimer Symptom Amelioration Study

[2020]Young blood plasma reduces Alzheimer’s disease-like brain pathologies and ameliorates cognitive impairment in 3×TgAD mice

Results: Young plasma treatment improved short-term memory in the novel object recognition test and enhanced the spatial learning and memory in Morris water maze test and reversal Morris water maze test. Biochemical studies revealed that young plasma treatment reduced both tau and Aβ pathologies, as well as neuroinflammation in the mouse brain. However, we did not detect any significant changes in levels of synaptic proteins or the dentate gyrus neurogenesis in the mouse brain after the treatment with young plasma. Conclusions: These data indicate that young blood plasma not only ameliorates tau and Aβ pathologies but also enhances the cognitive function in 3×Tg-AD mice. These findings suggest that transfusion with young blood plasma could be a potentially effective treatment for AD.

[2022] Efficacy and safety of blood derivatives therapy in Alzheimer’s disease: a systematic review and meta-analysis

Chronic Kidney Disease (CKD)

Diabetes (Blood glucose levels) - meds eliminated or cut in half

Eczema

Energy Levels

Erectile Dysfunction

Graves' (Autoimmune ) - ophthalmic disease and -

Multiple Sclerosis

[51] Young Blood Plasma Multiple Sclerosis Study One-Month Results Show Dramatic Improvements in Critical…

Ocular (Eyesight improvement documented from 20/40 to 20/20)

Ostioperosis

Parkinson’s Disease

[2020] Safety of Plasma Infusions in Parkinson’s Disease

Young Plasma Infusions Significantly Improve Clinical Symptoms and UPDRS Scores in Patients with Parkinson’s Disease

Pain

Lower spine/back pain

Peripheral Neuropathy

Torn rotator cuff Pain,

Sleep

Scaropienia (muscle pathology)

Truma (Recovery from Tramatic Injuries, Surgery or Illness)

Some studies have explored the use of young plasma for recovery enhancement post-surgery or in critical illness contexts. However, these studies often lacked robust design and did not conclusively establish efficacy.

 ◉ First person experiences with Young Plasma

"I've long suspected that I had received young fresh frozen plasma in my infusions, as the difference was noticeable. Thanks again for including me in your study—I haven't felt that good in many years. I appreciate it and will follow your progress!" 2019

◉ Physicians Incorporating Young Plasma in their Practices:

◉ Plasma source and practitioners using yFFP in their practices.

Young plasma is available through providers that obtain plasma from Spectrum Plasma, a Texas based blood bank that has developed a state of the art blood banking facility. This plasma is sourced from young individuals between the ages of 18 and 24.

❖ Bellaire suburb of Houston:

• Dian Ginsberg MD FACOG ABAARM / The Ginstitute of Functional Medicine

Fellowship Metabolic Medical Institute/A4M

Advisor Functional Medicine University

Website: https://www.dianginsbergmd.com/

Email: dianginsberg.md@gmail.com

❖ Arlington suburb of Dallas:

• Jeffrey Gladden, MD, FACC / Gladden Longevity

Website: https://www.gladdenlongevity.com 

Email: gladdenj@gladdenlongevity.com  

• Physician Not Identified on site / Resurgence Wellness

Website: https://resurgencewellness.com

Email: chrischappell@resurgencewellness.com  

❖ Austin:

• Ddaniel Stickler MD / Apeiron Zoh

Website: https://apeironzoh.com 

Email: drstickler@apeironcenter.com  

• Khanh Nguyen, M.D. / Anti-Aging & Regenerative Medicine

Website: https://austinregen.com

Email: austinregen67@gmail.com 

• No Primary Care Practitioner Identified / Everspan

Website: https://everspanlife.com

Email: drjulie@everspanlife.com

❖ San Antonio:

• Dr. Derek Guillory / Root Causes

Website: https://rootcauses.com

Email: dg@rootcauses.com 

Website: http://www.littlealsace.com/?page_id=10

Email: laucc.neel@gmail.com 

❖ Houston:

• Stanley C. Jones M.D. / Regenerative Health & Wellness

Website: https://stanleycjonesmd.com

Email: stanley.jones@yahoo.com 

• Dr. Langley and Dr. Gallegosa / Thrive Medical Clinic

Website: https://todayithrive.com

Email: dr.g@thrivemedicineclinic.com 

◉ Young Plasma Videos

◉ References

Literature Excerpts (Indented Text) Demonstrating the

Therapeutic and Age Regressive Potential of Young Plasma

[1][1864] [Bert P. De la greffe animale

[2][1957] Parabiosis Between Old and Young Rats

[3][1972] Mortality in Syngeneic Rat Parabionts of Different Chronological Age

[4][2005] Rejuvenation of aged progenitor cells by exposure to a young systemic environment

[5][2010] Platelets Contribute to Allograft Rejection Through Glutamate Receptor Signaling

[6][2014] Aged Mice Repeatedly Injected with Plasma from Young Mice: A Survival Study

[7][2014] Young blood reverses age-related impairments in cognitive function and synaptic plasticity in mice

[8][2015] Can we reverse the ageing process by putting young blood into older people?

{An excellent article detailing the early researchers that were instrumental is exposing the potential of young plasma.}

[9][2017] The Fountain of Youth: A tale of parabiosis, stem cells, and rejuvenation

[10][2017] Getting old through the blood: circulating molecules in aging and senescence of cardiovascular regenerative cells.

[11][2018] Rejuvenation of brain, liver and muscle by simultaneous pharmacological modulation of two signaling determinants, that change in opposite directions with age

[12][2019] Exosomes: biogenesis, biologic function and clinical potential

[13][2019] Undulating changes in human plasma proteome profiles across the lifespan

[14][2019] On the length, weight and GC content of the human genome

[15][2019] Looking to Young Blood to Treat the Diseases of Aging

[16][2019] Young plasma ameliorates aging-related acute brain injury after intracerebral hemorrhage

[17] [2019] Undulating Changes in Human Plasma Proteome Profiles Across the Llifespan

[18][2020] Plasma dilution improves cognition and attenuates neuroinflammation in old mice

[19][2020]  Reversing age- dual species measurement of epigenetic age with a single  clock

[20][2020] Rejuvenation of three germ layers tissues by exchanging old blood plasma with saline-albumin

[21][2020] Circulating anti-geronic factors from heterochonic parabionts promote vascular rejuvenation in aged mice- transcriptional footprint of mitochondrial protection, attenuation of oxidative stress, and rescue of endothelial function by young blood

[22][2020] Can Blood-Circulating Factors Unveil and Delay Your Biological Aging?

[23] [2020]  Data mining of human plasma proteins generates a multitude of highly predictive aging clocks that reflect different aspects of aging

[24][2021] Prospects for assessing the biological and immunological age of a person by blood factors

[25][2021] Plasma from Young Rats Injected into Old Rats Induce Antiaging Effects

[26][2021] Diverse plasma membrane protrusions act as platforms for extracellular vesicle shedding

[27][2021] Friends and foes: Extracellular vesicles in aging and rejuvenation (Introduction)

[28][2021] The aging systemic milieu negatively regulates neurogenesis and cognitive function

[29][2022] Old plasma dilution reduces human biological age - a clinical study

[30] [2022] Circulating plasma factors involved in rejuvenation

[31][2022] Anti-Aging Composition Use Thereof US 2022/0233587 A1

[32][2022] Umbilical cord plasma concentrate has beneficial effects on DNA methylation GrimAge and human clinical biomarkers

[33][2023] Finding a fountain of youth in the blood

[34][2023] Multi-omic rejuvenation and lifespan extension on exposure to youthful circulation

[35][2023] Mechanism of mesenchymal stem cells and exosomes in the treatment of age-related diseases

[36][2023] Reversal of biological age in multiple rat organs by young porcine plasma fraction

[37][2023 Intranasal Delivery of Endothelial Cell-Derived Extracellular Vesicles with Supramolecular Gel Attenuates Myocardial Ischemia-Reperfusion Injury

[38][2023] Endothelial cells release microvesicles that harbor multivesicular bodies

[39][2023] Young plasma transfer recovers decreased sperm counts and restores epigenetics in aged testis

This article contains an excellent overview of the benefits seen in animal models thus far.

Early studies investigating the effect of systemic factors in blood plasma on aging and lifespan showed positive effects of young plasma on quality of life in aged animals (Kennedy et al., 2014). For instance, in an injury model, it has been stated that there are significant differences between the regeneration levels of skeletal muscle in an elderly indi- vidual receiving young blood plasma compared to an elderly individual not receiving plasma (Conboy et al., 2005). In another study, it was reported that age-related reductions in pancreatic beta cell proliferation returned to youthful levels only 2–3 weeks after sharing young plasma, and improvements in renal aging parameters were observed in elderly individuals whose young plasma was shared (Huang et al., 2018). In a study conducted to improve the age-related brain dysfunction, it has been observed that young blood plasma affected the increasing adult neurogenesis and enhanced hippocampal synaptic plasticity in cogni- tional levels and also has curative effect (Villeda et al., 2014). In liver damage due to age-related impaired autophagy, it has been suggested that application of young plasma moderately reduces liver damage by restoring the dysfunctional autophagy process in aged rats; therefore, young plasma has a beneficial property in ameliorating aging-related organ damage (Liu et al., 2018). Many studies similar to the above have shown the healing properties of youth plasma in different tissues/ organs by certain cellular processes/paths in favour of healthy aging but it is not known how the epigenetic mechanisms are affected by these transfers. It is very important point because aging causes abnormality in epigenetic mechanisms which end up with epigenetic disorders.

[40][2024] Young Plasma Rejuvenates Blood DNA Methylation Profile, Extends Mean Lifespan, and Improves Physical Appearance in Old Rats

Research shows that young blood can rejuvenate old individuals by transferring cells, vesicles, and molecules that restore function and organ integrity. A study involving old female rats compared those receiving young rat plasma injections (Group T) with untreated controls (Group C). The treated group showed no deaths between ages 26 and 30 months, whereas control group mortality began at 26 months. Blood DNA methylation (DNAm) analyses indicated that DNAm age increased rapidly in youth, stabilized after 27 months, and remained consistently lower in treated rats than in controls until their natural death. Treated and control groups exhibited distinct DNA methylation profiles. Promoter methylation analysis revealed enrichment in gene ontology terms associated with insulin-like factors and immune-related cytokines and chemokines. The findings suggest that young plasma therapy is a promising noninvasive strategy for epigenetic rejuvenation and health enhancement in the elderly.

[41][2024] Clinical applications of stem cell-derived exosomes

[42][2024] Small extracellular vesicles from young plasma reverse age-related functional declines by improving mitochondrial energy metabolism

Recent research into heterochronic parabiosis has shown significant rejuvenating effects of young blood on old tissues, but the precise mechanisms are not fully understood. This study illustrates that small extracellular vesicles (sEVs) from young mice plasma can reverse aging effects at molecular, mitochondrial, cellular, and physiological levels. Intravenous injections of these sEVs into aged mice extended their lifespan, reduced signs of aging, and improved function in various tissues. Proteomic analysis of treated tissues revealed major alterations in protein expressions linked to metabolic processes. Mechanistically, young sEVs were found to enhance PGC-1α expression, both in vitro and in vivo, via their microRNA content. This upregulation of PGC-1α improved mitochondrial functions and addressed mitochondrial deficits, thus countering age-related degeneration and dysfunction in aged tissues. The study underscores the potential of young sEVs to rejuvenate aged cells by enhancing mitochondrial energy metabolism.

[43][2024] Young Plasma Rejuvenates Blood DNA Methylation Profile, Extends Mean Lifespan, and Improves Physical Appearance in Old Rats

There is increasing evidence that young plasma can have restorative effects in aging, especially noted in the brains of old rats and in age-related diseases. Studies have shown that human cord plasma can enhance synaptic plasticity and cognition in aged mice, potentially through a factor called tissue inhibitor of metalloproteinases 2. Furthermore, administration of plasma proteins in old rats has been linked to a significant reversal of epigenetic age. In a recent study, it was demonstrated for the first time that continuous treatment of old rats with young rat plasma not only moderately rejuvenates them epigenetically but also extends their lifespan and improves their physical appearance, such as smoother fur. This effect is possibly mediated by the IGF-1/IIS system and cytokine and chemokine networks. This suggests that young plasma therapy might be a natural and minimally invasive way to promote epigenetic rejuvenation and overall health improvement. Summary by ChatGPT.

[44][2024] Aging and age-related diseases with a focus on therapeutic potentials of young blood/plasma

[45] https://www.age-regression.com/rir

[46] Personal Communications

Definitions of Terms Utilized on this Page

 Age gap

The difference between a biological age measurement and the expectation of that measurement for a given chronological age.

Heterochronic parabiosis

An experimental paradigm where the circulatory systems of a young and old animal are surgically joined together.

Biological age

The level of biological functioning of an organism, organ or cell as assessed in comparison to an expected level of function for a given chronological age.

CERS

The Chrono-Epigenetic Regulation System (CERS) Interface between environmental, biological and psychological control system of development, immunity and aging. The three layers involved are Chronokines, epigenetic and genetic layers. Combine they form a complex and dynamic regulatory processes governing human physiological and aging control.

Chronological age

The amount of time an organism has been alive for, typically measured in years for humans and tracked by birthdays.

Partial epigenetic reprogramming

Delivery of factors that can de-differentiate cells into induced pluripotent stem cells, typically short term, to de-age the epigenetic state of cells.

Proteomics

Proteomics, the large-scale study of the proteins, focuses on the systematic identification, quantification, and analysis of all proteins in a biological sample. It aims to understand the structure, function, and interactions of the entire protein complement of a cell line, tissue, or organism under specific conditions. Employing technologies like mass spectrometry, protein microarrays, and bioinformatics, proteomics analyzes protein expression, structure, post-translational modifications, and interactions. This field is crucial for understanding biological processes, diseases, and in the development of new therapies and diagnostics.

In human plasma, there are approximately 10,000 to 15,000 proteins and small molecules that can be detected with current technologies. This diverse range includes proteins, peptides, lipids, metabolites, and other biologically active compounds. The dynamic range of these protein concentrations is vast, making it a challenge to detect and quantify especially those present at low levels.

• Companies Developing Plasma or Plasma Derived Therapies

Alkahest: This company, now a subsidiary of Grifols, focuses on developing plasma formulations by pooling blood from young donors and selectively removing unwanted immune molecules. Alkahest’s research has primarily targeted neurological conditions like Alzheimer's and Parkinson's disease, exploring the cognitive benefits of plasma-derived productsThe company was co-founded in 2014 by Tony Wyss-Coray, a neurologist at Stanford University, after he published papers showing that the rejuvenating effect of parabiosis extended to the mouse brain. (Smithsonian Magazine)​.

[2020] Safety and tolerability of GRF6019 in mild‐to‐moderate Alzheimer's disease dementia

GRF6019 is a highly specialized plasma fraction developed by Alkahest in partnership with Grifols, designed for the treatment of neurodegenerative diseases like Alzheimer's. This therapy emerges from research indicating that certain components of plasma could potentially reverse aspects of aging in the brain due to their regenerative and anti-inflammatory properties.

The preparation of GRF6019 involves selecting approximately 400 proteins from plasma, with a focus on removing clotting factors and immunoglobulins to enhance safety and tolerability. This process ensures that the treatment does not require matching donor and recipient blood types, simplifying its administration. GRF6019 targets the enhancement of cognition, reduction of inflammation, and restoration of neurogenesis.

Clinical trials of GRF6019 have shown promising results in terms of safety and efficacy. It has completed Phase 2 trials for mild to moderate Alzheimer’s disease, with studies indicating that it was well-tolerated and participants showed stable or negligible decline in cognitive and functional measures over six months. The treatment is also being evaluated in patients with severe Alzheimer's, focusing on its safety, tolerability, and potential effects on patients' mental states and daily activities (AlzForum)​​ (Alkahest)​​ (Alzheimer's News Today)​.

For more detailed information, you can refer to Alkahest's updates on their clinical trials and therapeutic developments on their official website [Alkahest](https://www.alkahest.com/pipeline/akst-grf6019/).

Young blood cocktail stops Alzheimer's decline, early clinical trial reports

CSL Behring / CSL Plasma: This company is a major player in the global blood plasma products market, holding the largest market share in 2021. CSL Behring operates numerous plasma collection centers worldwide and focuses on innovative biotherapeutic products【7†source

Elevian: Elevian is developing treatments based on a specific blood-borne protein, GDF11, which has shown promise in preclinical studies to restore youthful characteristics in various tissues. The company is preparing to test its lab-grown version of GDF11 in human trials, aiming to treat age-related diseases like stroke【8†source】It was co-founded in 2018 by Amy Wagers, who was on the Stanford parabiosis revival team and is now a professor of stem-cell and regenerative biology at Harvard University.

Grifols: Based in Spain, Grifols is significant in the bioscience sector, providing plasma-based protein therapies. The company runs numerous plasma collection centers and focuses on expanding its plasma collection capacity through facility expansions and acquisitions (BCC Research Blog)​.

Takeda: Another leading company, Takeda specializes in plasma-derived therapies, particularly for rare diseases, operating over 200 plasma collection centers globally ​ (BCC Research Blog)​.

Spectrum Plasma: is a company that focuses on plasma collection and emphasizes contributing positively to the community by producing health-improving products. They adopt a fresh approach to how individuals can donate plasma and whole blood, providing immediate rewards to donors in the form of Tango gift cards. Their operations are based in multiple locations across the United States including California, Texas, and Nevada​ (Spectrum Plasma)​​ (Corporation Wiki)​.

• BLOGS:

Longevity on Reddit

(search for “Young Plasma”)

https://www.reddit.com/r/longevity/

Out With the Old Blood

Aging Matters; Aging Matters: Out With the Old Blood

Molecules in the Blood that Signal Self-Destruction

How Young Blood Differs from Old

• NOTES / FUTURE RESEARCH

[2022] Umbilical cord plasma concentrate has beneficial effects on DNA methylation GrimAge and human clinical biomarkers

[2022] Molecular hallmarks of heterochronic parabiosis at single-cell resolution

[2020] Blood Serum Stimulates p38-Mediated Proliferation and Changes in Global Gene Expression of Adult Human Cardiac Stem Cells

[2020] Analysis of epigenetic aging in vivo and in vitro: Factors controlling the speed and direction[2020]

[2020] Circulating plasma factors involved in rejuvenation

[2018] Plasma proteomic signature of age in healthy humans

[2021] Proteomics and Epidemiological Models of Human Aging

[2021] Proteomics in aging research- A roadmap to clinical, translational research