Fibroblast
Growth Factors
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Contents:
What do Growth Factors Do
What is Fibroblast Growth Factor (FGF)
Conjugated FGF
What is the anti-aging effect of FGF
Research and Medical Use
Contraindications
Conclusion
Growth factors (GF) are small
protein chains, commonly known as polypeptides that bind to
cell surface receptor sites and exert actions directly on the target cells.
This is generally done through cellular proliferation and or differentiation.
Some GFs exert a generalized effect, while others are cell and action specific.
There are many different classes of GFs. Some common ones are: Insulin-like
Growth Factor (IGF-1) which is responsible for much of the Growth Hormone
(GH) action in the body, Interleukins (IL), Fibroblast Growth Factors (FGF),
Transforming Growth Factor (TGF), Tumor Necrosis Factor (TNF), Epidermal
Growth Factor (EGF), Transforming Growth Factors-b (TGFs-b), and erythropoietin
(EPO).
GFs come from a wide variety of sources. Epithelial Growth Factors (EGF)
comes from sub maxillary gland, erythropoietin comes from the kidney, and
FGF comes from a wide range of cells. A unique family of growth factors
that are secreted primarily by leukocytes (white blood cells) are called
cytokines. When such cytokines are secreted by lymphocytes, they are called
lymphokines. Many of the lymphokines are also known as interleukins (ILs).
Not only are interleukins secreted by leukocytes, but they also retain the
ability to affect the cellular responses of leukocytes.
What do Growth Factors Do?
Different GFs have different jobs to do. Generally, all of them work at
the cellular level to:
Repair damaged cells
Enhance cellular proliferation
Maintain optimum function of the target organ
Rejuvenate aging tissues
While hormones are generally more specific and sometimes work through other
mediations elicited from their simulation of intermediate organs, GFs often
act directly on the target tissue and have a wide range of effects.
Its action is mostly stimulatory. It can also work synergistically
with other GFs or hormones to elicit a biological effect. Growth hormones,
for example, exert their effects in the body via Insulin-like Growth Factor
(IGF-1). In other words, it is the IGF-1 that actually carries out the function
of the growth hormone and not growth hormone itself.
What is Fibroblast Growth Factor (FGF)?
 FGF is a group of GFs that act on the fibroblast within the
body. Fibroblast are basic building blocks
of fibrous tissue, including the brain, nervous system, eye, blood vessels,
heart, stomach, skin, liver, kidney, muscle and bone. In fact,
most cells within these organs possess receptors for FGF and therefore are
susceptible to its biological effect.
There are at least 19 distinct members of the FGF family, which interact
with at least 4 distinct types of cell-surface receptors. It is evident
that the amount of FGF is essential for optimum body function, and disruption
of FGF can lead to disease states, including achondroplasia and craniosynotosis
syndromes.
Conjugated FGF
FGF can be bound to inert, non-toxic polymers to form a conjugated molecule.
This is usually done through a series of chemical reactions. Substances
commonly used as polymers include polysaccharides or muco-adhesives.
FGF is a small protein that can be easily denatured when exposed to heat
or acid. Ingesting FGF, for example, will expose FGF to gastric acid, which
will quickly denature it. When the FGF is
conjugated, the protein is more stable and protected from the digestive
enzymes, for example. Conjugation
can further program the FGF's release from its carrier in order to ensure
that the desired action of the GF, on a specific site, is maintained.
What is the anti-aging effect of FGF?
The natural progression of the aging process is due to cellular degeneration.
Oxidative stress and free radical pathology has been well studied, in this
respect, as a causative factor. FGF helps
maintain the target organs that contain fibrous tissue; including the eyes,
heart, brain, skin, and the musculoskeletal system. It helps repair
damaged tissue. For example, FGF can help restore
normalcy in injured nerve tissue or damaged blood vessels in order to prevent
further clotting or stokes. In the case of a duodenal ulcer, it can reduce
healing time. The fortification and re-growth of the epidermis and its underlying
circulation will lead to healthier skin and fewer wrinkles.
Non-damaged aging cells can also benefit from FGFs. Laboratory studies,
for example, have shown that cells that are unable to replace themselves
(such as eye tissue), can be stimulated to renew cell layers. An example
of this is the pigmented layer in the eye.
Body parts that respond to biological stimulation of FGF include:
Nervous system (brain, central nervous system)
Cardiovascular system (heart, circulatory system)
Skin (dermis, epidermis, and underlying circulatory system)
Eye (cornea and retina)
Gastro-intestinal system (stomach and intestine)
Hair (hair follicle and the sub-scalp circulatory system)
Musculo-skeletal system (muscle, bone, cartilage)
Liver and Kidney (target organ cells)
Research and Medical Use
Intense research is underway to further study the therapeutic use of FGF
in combating disease and deterring the aging process. The National Institute
of Health (NIH), for example, is conducting a study on using FGF to treat
coronary heart disease in lieu of coronary bypass surgery.
 Other animal studies include
the use of FGF in:
Treatment of duodenal ulcer
Treatment of Adult macular degeneration of the eye
Treatment of burns wounds
Treatment of spinal cord injuries
Repair of bone and cartilage damage.
Contraindications
Commercially available FGF is of very low dosage and classified as a food
supplement under FDA regulations. Side effects have not been reported. Due
to its stimulatory effect on fibrous tissues, active cancer or pregnant
patients should avoid taking this as a food supplement unless cleared by
a physician.
Conclusion
Fibroblast Growth Factors (FGF) is a class of small protein polypeptide
chains that have specific actions on the cellular function. It works
hand in hand with hormones, while exerting its own unique properties. Due
to the omnipresence of fibrous tissues in the body, FGF is an important
anti-aging tool. Target organs, including skin, heart, brain, nervous system,
musculo-skeletal system function, can be enhanced by FGF action thus making
FGF an important component to any anti-aging
program.
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About The Author
Michael Lam, M.D., M.P.H., A.B.A.A.M.
is a specialist in Preventive and Anti-Aging Medicine. He is currently the Director
of Medical Education at the Academy of Anti-Aging Research, U.S.A. He received
his Bachelor of Science degree from Oregon State University, and his Doctor
of Medicine degree from Loma Linda University School of Medicine, California.
He also holds a Masters of Public Health degree and is Board Certification
in Anti-aging Medicine by the American Board of Anti-Aging Medicine. Dr. Lam
pioneered the formulation of the three clinical phases of aging as well as the
concept of diagnosis and treatment of sub-clinical age related degenerative
diseases to deter the aging process. Dr. Lam has been published extensively
in this field. He is the author of The Five Proven Secrets to Longevity
(available on-line). He also serves as editor of the Journal of Anti-Aging
Research.
For More Information
For the latest anti-aging related health issues, visit Dr. Lam
at www.LamMD.com. Feel free to email
Dr. Lam at dr@LamMD.com if you have any questions.
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©2002 Michael Lam, M.D. All Rights Reserved.
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