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The age-reversal premise we are espousing is the subject of three books written by highly respected medical doctors. These books provide a persuasive compilation of research findings and clinical experience to document the safety and efficacy of using this approach to treat aging. The books fail, however, to provide an aggressive therapeutic plan of action. In this protocol, the Foundation provides a novel step-by-step program to enable members to immediately take advantage of this new information.
Male Hormones and Aging
As men age past year 40, hormonal changes occur that perceptibly inhibit physical, sexual, and cognitive function. The outward appearance of a typical middle-aged male shows increased abdominal fat and shrinkage of muscle mass, a hallmark effect of hormone imbalance. Loss of a feeling of well-being, sometimes manifesting as depression, is a common psychological complication of hormone imbalance (94-97, 271).
Until recently, these changes were attributed to "growing old," and men were expected to accept the fact that their bodies were entering into a long degenerative process that would someday result in death.
A remarkable amount of data has been compiled indicating that many of the diseases that middle-aged men begin experiencing, including depression, fatigue, abdominal weight gain, alterations in mood and cognition, decreased libido, erectile dysfunction, prostate disease, and heart disease, are directly related to hormone imbalances that are correctable with currently available drug and nutrient therapies. These symptoms usually onset around age 40-50, although with smokers the onset is significantly earlier (290-293).
To the patient's detriment, conventional doctors are increasingly prescribing drugs to treat depression, elevated cholesterol, angina, and a host of other diseases that might be caused by an underlying hormone imbalance.
If doctors checked their male patients' blood levels of estrogen, testosterone, thyroid, and DHEA (instead of prescribing drugs to treat symptoms), they might be surprised to learn that many problems could be eliminated by adjusting hormone levels to fit the profile of a healthy 21-year-old male.
Few physicians are familiar with the hormone blood tests that should be ordered for men, nor do they have the experience required to properly adjust hormones to reverse the degenerative changes that begin in mid-life. This protocol will provide the patient and physician with the information necessary to safely modulate hormone levels for the purpose of preventing and treating many of the common diseases associated with growing older.
Too Much Estrogen
The most significant hormone imbalance in aging men is a decrease in free testosterone, while estrogen levels remain the same or increase precipitously. As men grow older, they experience a variety of mechanisms from the dual effects of having too little testosterone and excess estrogen. The result is a testosterone-estrogen imbalance that directly causes many of the debilitating health problems associated with normal aging (1-12, 28).
One cause of hormone imbalance in men is that their testosterone is increasingly converted to estrogen. One report showed that estrogen levels of the average 54-year-old man are higher than those of the average 59-year-old woman (1, 5, 13-18, 48).
The reason that testosterone replacement therapy does not work by itself for many men is that exogenously administered testosterone may convert (aromatize) into even more estrogen, thus potentially worsening the hormone imbalance problem in aging males (i.e., too much estrogen and not enough free testosterone) (21, 26). While there are studies showing that testosterone replacement therapy does not increase estrogen beyond normal reference ranges, we will show later how the standard laboratory reference ranges do not adequately address the issue of estrogen overload (4, 8, 9, 17, 22-25, 27, 29-32).
Estrogen is an essential hormone for men, but too much of it causes a wide range of health problems. The most dangerous acute effect of excess estrogen and too little testosterone is an increased risk of heart attack or stroke (39-43, 261-270). High levels of estrogen have been implicated as a cause of benign prostatic hypertrophy (prostate enlargement) (35-44, 46, 47). One mechanism by which nettle root extract works is to block the binding of growth-stimulating estrogen to prostate cells (42-44, 48-50).
When there is too little testosterone present, estrogen attaches to testosterone cell receptor sites throughout the body and creates many problems in aging men. In youth, low amounts of estrogen are used to turn off the powerful cell-stimulating effects of testosterone. As estrogen levels increase with age, testosterone cell stimulation may be locked in the "off" position, thus reducing sexual arousal and sensation and causing the loss of libido so common in aging men (94, 99, 259).
High serum levels of estrogen also trick the brain into thinking that enough testosterone is being produced, further slowing the natural production of testosterone. This happens when estrogen saturates testosterone receptors in the hypothalamus region of the brain. The saturated hypothalamus then stops sending out a hormone to the pituitary gland to stimulate secretion of luteinizing hormone that the gonads require to produce testosterone. High estrogen can thus shut down the normal testicular production of testosterone (1, 53, 54, 271-277).
One further complication of excess estrogen is that it increases the body's production of sex hormone-binding globulin (SHBG) (280). SHBG binds free testosterone in the blood and makes it unavailable to cell receptor sites (51, 52, 55, 56).
Based on the multiple deleterious effects of excess estrogen in men, aggressive action should be taken to reduce estrogen to a safe range if a blood test reveals elevated levels. We will discuss the appropriate blood tests and steps that can be taken to lower estrogen levels later in this protocol.
The Critical Importance of Free Testosterone
Testosterone is much more than a sex hormone. There are testosterone receptor sites in cells throughout the body, most notably in the brain and heart (60, 180). Youthful protein synthesis for maintaining muscle mass and bone formation requires testosterone (57, 59, 61-74, 87-90, 261- 264, 287). Testosterone improves oxygen uptake throughout the body, helps control blood sugar (68, 75-80), regulates cholesterol (67, 69, 81), and maintains immune surveillance (82, 83). The body requires testosterone to maintain youthful cardiac output and neurological function (58, 65). Testosterone is also a critical hormone in the maintenance of healthy bone density (59, 66, 67, 84-86), muscle mass (65-67, 87-90, 287), and red blood cell production (67, 69, 91-93, 98).
Of critical concern to psychiatrists are studies showing that men with depression have lower levels of testosterone than do control subjects (94-98). For some men, elevating free testosterone levels could prove to be an effective antidepressant therapy. There is a basis for free testosterone levels being measured in men with depression and for replacement therapy being initiated if free testosterone levels are low normal or below normal.
Testosterone is one of the most misunderstood hormones. Body builders tarnished the reputation of testosterone by putting large amounts of synthetic testosterone drugs into their young bodies. Synthetic testosterone abuse can produce detrimental effects (34), but this has nothing to do with the benefits a man over age 40 can enjoy by properly restoring his natural testosterone to a youthful level.
Conventional doctors have not recommended testosterone replacement therapy because of an erroneous concern that testosterone causes prostate cancer. As we will later show, fear of prostate cancer is not a scientifically valid reason to avoid testosterone modulation therapy.
Another concern that skeptical physicians have about prescribing testosterone replacement therapy is that some poorly conducted studies showed it to be ineffective in the long-term treatment of aging. These studies indicate anti-aging benefits when testosterone is given, but the effects often wear off. What physicians fail to appreciate is that exogenously administered testosterone can convert to estrogen in the body. The higher estrogen levels may negate the benefits of the exogenously administered testosterone. The solution to the estrogen-overload problem is to block the conversion of testosterone to estrogen in the body. Numerous studies show that maintaining youthful levels of free testosterone can enable the aging man to restore strength, stamina, cognition, heart function, sexuality, and outlook on life, i.e., to alleviate depression (261-270). A study in Drugs and Aging (1999) suggested that androgen therapy can result in polycythemia (increased numbers of red blood cells) causing an increase in blood viscosity and risk of clotting (303). For many aging men, however, borderline anemia is a greater concern than red blood cell overproduction. When men are deprived of testosterone during prostate cancer therapy, anemia frequently manifests. Life Extension has not seen cases of polycythemia in men replacing testosterone to physiological youthful ranges. In other words, too much testosterone could cause problems, but replacing testosterone to that of a healthy 21-year-old should not produce the side effects that some doctors are unduly concerned about. As you will read in the section entitled "Testosterone and the Heart," it appears that testosterone replacement therapy provides significant beneficial effects against cardiovascular disease.
Why Testosterone Levels Decline
Testosterone production begins in the brain. When the hypothalamus detects a deficiency of testosterone in the blood, it secretes a hormone called gonadotrophin-releasing hormone to the pituitary gland. This prompts the pituitary to secrete luteinizing hormone (LH), which then prompts the Leydig cells in the testes to produce testosterone.
In some men, the testes lose their ability to produce testosterone, no matter how much LH is being produced. This type of testosterone deficiency is diagnosed when blood tests show high levels of LH and low levels of testosterone. In other words, the pituitary gland is telling the testes (by secreting LH) to produce testosterone, but the testes have lost their functional ability. So the pituitary gland vainly continues to secrete LH because there is not enough testosterone in the blood to provide a feedback mechanism that would tell the pituitary to shut down. In other cases, the hypothalamus, or pituitary gland, fails to produce sufficient amounts of LH, thus preventing healthy testes from secreting testosterone. Blood testing can determine whether sufficient amounts of LH are being secreted by the pituitary gland and help determine the appropriate therapeutic approach. If serum (blood) testosterone levels are very low, it is important to diagnose the cause, but no matter what the underlying problem, therapies exist today to safely restore testosterone to youthful levels in any man (who does not already have prostate cancer).
As indicated earlier, a major problem that aging men face is not low production of testosterone, but excessive conversion of testosterone to estrogen. Specific therapies to suppress excess estrogen and boost free testosterone back to youthful physiological levels will be discussed later.
Source: Courtesy of Stephen Strum, M.D.
The Effects of Testosterone on Libido
Sexual stimulation and erection begin in the brain when neuronal testosterone-receptor sites are prompted to ignite a cascade of biochemical events that involve testosterone-receptor sites in the nerves, blood vessels, and muscles. Free testosterone promotes sexual desire and then facilitates performance, sensation, and the ultimate degree of fulfillment.
Without adequate levels of free testosterone, the quality of a man's sex life is adversely affected and the genitals atrophy. When free testosterone is restored, positive changes can be expected in the structure and function of the sex organs. (It should be noted that sexual dysfunction can be caused by other factors unrelated to hormone imbalance. An example of such a factor is arteriosclerotic blockage of the penile arteries.)
The genital-pelvic region is packed with testosterone receptors that are ultra-sensitive to free testosterone-induced sexual stimulation. Clinical studies using testosterone injections, creams, or patches have often failed to provide a long-lasting, libido-enhancing effect in aging men (98). We now know why. The testosterone can be converted to estrogen. The estrogen is then taken up by testosterone receptor sites in cells throughout the body. When an estrogen molecule occupies a testosterone receptor site on a cell membrane, it blocks the ability of serum testosterone to induce a healthy hormonal signal. It does not matter how much serum free testosterone is available if excess estrogen is competing for the same cellular receptor sites.
Estrogen can also increase the production of sex hormone-binding globulin (SHBG), which binds the active free testosterone into an inactive "bound testosterone." Bound testosterone cannot be picked up by testosterone receptors on cell membranes. For testosterone to produce long-lasting, libido-enhancing effects, it must be kept in the "free" form (not bound to SHBG) in the bloodstream. It is also necessary to suppress excess estrogen because this hormone can compete for testosterone receptor sites in the sex centers of the brain and the genitals.
Restoring youthful hormone balance can have a significant impact on male sexuality (99-102).
Testosterone and the Heart
Normal aging results in the gradual weakening of the heart, even in the absence of significant coronary artery disease. If nothing else kills the elderly male, his heart just stops beating at some point.
Testosterone is a muscle-building hormone, and there are many testosterone-receptor sites in the heart (57). The weakening of the heart muscle can sometimes be attributed to testosterone deficiency (103-108). Testosterone is not only responsible for maintaining heart muscle protein synthesis, it is also a promoter of coronary artery dilation (109-113) and helps to maintain healthy cholesterol levels (81, 114).
There are an ever-increasing number of studies indicating an association between high testosterone and low cardiovascular disease rates in men (81). In the majority of patients, symptoms and EKG measurements improve when low testosterone levels are corrected. One study showed that blood flow to the heart improved 68.8% in those receiving testosterone therapy (9). In China, doctors are successfully treating angina with testosterone therapy (9, 115, 116).
The following list represents the effects of low testosterone on cardiovascular disease:
Cholesterol, fibrinogen, triglycerides, and insulin levels increase (30-33).
Coronary artery elasticity diminishes.
Blood pressure rises.
Human growth hormone (HGH) declines (weakening heart muscle).
Abdominal fat increases (increasing the risk of heart attack).
Those with cardiovascular disease should have their blood tested for free testosterone and estrogen. Some men (with full cooperation from their physicians) may be able to stop taking expensive drugs to stimulate cardiac output, lower cholesterol, and keep blood pressure under control, if they correct a testosterone deficit or a testosterone-estrogen imbalance. Recently, a compelling study of 1100 men showed that those with serum DHEA-S in the lowest quarter (<1.6 µg/mL) were significantly more likely to incur symptoms of heart disease (295), and in a review of several studies, other authors have confirmed this association (296). DHEA is produced by the adrenal gland and is a precursor hormone for the manufacture of testosterone. (See the DHEA and Pregnenolone Precautions protocol.)
Despite numerous studies substantiating the beneficial effects of testosterone therapy in treating heart disease, conventional cardiologists continue to overlook the important role this hormone plays in keeping their cardiac patients alive (9, 30, 31, 77, 93, 111-113, 115, 116, 261-270).
Testosterone and the Prostate Gland
Many doctors will tell you that testosterone causes prostate disease. The published scientific literature indicates otherwise.
As readers of Life Extension Magazine learned in late 1997, estrogen has been identified as a primary culprit in the development of benign prostate hypertrophy (prostate enlargement) (117-119). Estrogen has been shown to bind to SHBG in the prostate gland and cause the proliferation of epithelial cells in the prostate (124, 182-184). This is corroborated by the fact that as men develop benign prostate enlargement, their levels of free testosterone plummet, while their estrogen levels remain the same or are rising. As previously discussed, aging men tend to convert their testosterone into estrogen. The published evidence shows that serum levels of testosterone are not a risk factor for developing benign prostate disease (8, 36, 41, 117-137).
The major concern that has kept men from restoring their testosterone to youthful levels is fear of prostate cancer. The theory is that since most prostate cancer cell lines need testosterone to proliferate, it is better not to replace the testosterone that is lost with aging. The problem with this theory is that most men who develop prostate cancer have low levels of testosterone, and the majority of published studies show that serum testosterone levels do not affect one's risk for contracting prostate cancer.
Since there is such a strong perception that any augmentation of testosterone can increase the risk of prostate cancer, we did a MEDLINE search on all the published studies relating to serum testosterone and prostate cancer. The abstracts at the end of this protocol provide quotations from the published literature as it relates to the issue of whether testosterone causes prostate disease. Of the 27 MEDLINE studies found, 5 studies indicated that men with higher testosterone levels had a greater incidence of prostate cancer, whereas 21 studies showed that testosterone was not a risk factor and 1 study was considered neutral.
Before starting a testosterone replacement program, men should have a serum PSA test and a digital rectal exam to rule out prostate cancer. Nothing is risk free. A small minority of men with low testosterone and prostate cancer will not have an elevated PSA or palpable lesion detectable by digital rectal exam. If these men use supplemental testosterone, they risk an acute flare-up in their disease state. That is why PSA monitoring is so important every 30 to 45 days during the first 6 months of any type of testosterone augmentation therapy. If an underlying prostate cancer is detected because of testosterone therapy, it is usually treatable by non-surgical means.
Please remember that testosterone does not cause acute prostate cancer, but if you have existing prostate cancer and do not know it, testosterone administration is likely to boost PSA sharply and provide your doctor with a quick diagnosis of prostate cancer (and an opportunity for very early treatment). We acknowledge that some aging men will not want to take this risk.
As stated above, the MEDLINE score was 21 to 5 against the theory that testosterone plays a role in the development of prostate cancer. None of these studies took into account the prostate cancer prevention effects for men who take lycopene, selenium, and vitamins A and E (135-144), nor did they factor in possible prostate disease preventives such as saw palmetto, nettle, soy, and pygeum (42-44, 145-170, 172).
In Dr. Jonathan Wright's book, Maximize Your Vitality & Potency, a persuasive case is made that testosterone and DHEA actually protect against the development of both benign and malignant prostate disease (305). Dr. Wright also points out that natural therapies such as saw palmetto, nettle, and pygeum provide a considerable degree of protection against the alleged negative effects that higher levels of testosterone might have on the prostate gland.
We eagerly await the results of more studies, but the fear of developing prostate cancer in the future should not be a reason to deprive your body today of the life-saving and life-enhancing benefits of restoring a youthful hormone balance.
Once a man has prostate cancer, testosterone therapy cannot be recommended because most prostate cancer cells use testosterone as a growth promoter. Regrettably, this denies prostate cancer patients the wonderful benefits of testosterone therapy. Men with severe benign prostatic hyperplasia (prostate enlargement) should approach testosterone replacement cautiously. It would be prudent for those with prostate enlargement who are taking testosterone replacement therapy to also use the drug Proscar (finasteride) to inhibit 5-alpha-reductase levels, thereby suppressing the formation of dihydrotestosterone (DHT) (171-182). DHT is ten times more potent than testosterone in promoting prostate growth, and suppressing DHT is a proven therapy in treating benign prostate enlargement. Saw palmetto extract suppresses some DHT in the prostate gland, but saw palmetto's effectiveness in alleviating symptoms of prostate enlargement probably has more to do with
Its blocking of alpha-adrenergic receptor sites on the sphincter muscle surrounding the urethra. (This is how the drug Hytrin works.)
Its inhibition of estrogen binding to prostate cells (such as nettle).
Its inhibition of the enzyme 3-ketosteroid (which causes the binding of DHT to prostate cells).
Its anti-inflammatory effect on the prostate.
Note: Men with severe prostate enlargement may also consider using the drug Arimidex (0.5 mg, twice a week) to suppress excess levels of estrogen. Estrogen can worsen prostate enlargement and supplemental testosterone can elevate estrogen if an aromatase-inhibiting drug such as Arimidex is not used.
It is unfortunate that many people still think that restoring testosterone to youthful levels will increase the risk of prostate disease. This misconception has kept many men from availing themselves of this life-enhancing and life-saving hormone.
While it is clear that excess estrogen causes benign prostate enlargement, the evidence for excess estrogen's role in the development of prostate cancer is uncertain (8, 41, 117-134, 182-217, 236). Some studies show that elevated estrogen is associated with increased prostate cancer risk, while other studies contradict this finding. For more information on testosterone, estrogen, and the prostate gland, refer to the February 1999 issue of Life Extension Magazine (182-217, 306).
Correcting a Hormone Imbalance
A male hormone imbalance can be detected through use of the proper blood tests and can be corrected using available drugs and nutrients. The following represents a step-by-step program to safely restore youthful hormone balance in aging men:
Step 1: Blood testing
The following initial blood tests are recommended for any man over age 40:
Complete blood count and chemistry profile to include liver-kidney function, glucose, minerals, lipids, and thyroid (TSH) Free and Total Testosterone
Estradiol (estrogen)
DHT (dihydrotestosterone)
DHEA
PSA
Homocysteine
Luteinizing hormone (LH) (optional)
Sex Hormone Binding Globulin (SHBG) optional
Step 2: Interpretation of free testosterone, estrogen, and total testosterone blood test results
One can easily determine if they need testosterone replacement or estrogen suppression by adhering to the following guidelines:
Free testosterone
Free testosterone blood levels should be at the high-normal of the reference range. We define high-normal range as the upper one third of the reference range. Under no circumstances should free or total testosterone be above the high end of the normal range.
What too often happens is that a standard laboratory "reference range" deceives a man (and his physician) into believing that proper hormone balance exists because the results of a free testosterone test fall within the "normal" range. The following charts show a wide range of so-called "normal" ranges of testosterone for men of various ages. While these normal ranges may reflect population "averages," the objective for most men over age 40 is to be in the upper one-third testosterone range of the 21- to 29-year-old group. Based on the following reference range chart from LabCorp, this means that optimal free testosterone levels should be between 21-26.5 ng/dL in aging men.
Reference Intervals for Free Testosterone from LabCorp
20-29 years 9.3-26.5 pg/mL
30-39 years 8.7-25.1 pg/mL
40-49 years 6.8-21.5 pg/mL
50-59 years 7.2-24.0 pg/mL
60+ years 6.6-18.1 pg/mL
An example of how this chart can be deceptive would be if a 50-year-old man presented with symptoms of testosterone deficiency (depression, low energy, abdominal obesity, angina, etc.), but his blood test revealed his free testosterone to be 9 pg/mL. His doctor might tell him he is fine because he falls within the normal "reference range." The reality may be that to achieve optimal benefits, testosterone levels should be between 21-26.5 pg/mL. That means a man could have less than half the amount of testosterone needed to overcome symptoms of a testosterone deficiency, but his doctor will not prescribe testosterone replacement because the man falls within the "average" parameters. That is why it is so important to differentiate between "average" and "optimal." Average 50-year-old men often have the symptoms of having too little testosterone. Yet since so many 50-year-old men have lower than desired testosterone levels, this is considered to be "normal" when it comes to standard laboratory reference ranges.
The Life Extension Foundation would like to point out that there is disagreement between clinicians and laboratories on the best method for measuring testosterone status. There are different schools of thought as to which form of testosterone should be measured and which analytical procedure provides the most accurate assessment of metabolic activity. We believe that direct testing for free testosterone is the best way to test for testosterone activity, as free testosterone is active testosterone and consists of only 1-2% of total testosterone. Total testosterone can be good for general testing. The four main methods presently used for analyzing free testosterone are:
Direct, Free Testosterone by Direct Analog/Radioimmunoassay (RIA) Testosterone Free by Ultrafiltration (UF)
Testosterone Free by Equilibrium Tracer Dialysis (ETD)
Testosterone Free and Weakly Bound by Radioasssay (FWRA)
The latter three test methods are older, more complicated methods that are technically demanding. The direct RIA test has a number of commercial test kits available, and they are better used in today's automated equipment, making this test less tedious and requiring a smaller (less) sample. These advantages have convinced many laboratories and clinics to prefer direct RIA testing for Free Testosterone. The Life Extension Foundation agrees with this assessment, and therefore uses and recommends the Direct, Free Testosterone test with the above-mentioned reference levels.
Consequently, if your doctor tests your free testosterone, be sure you know the analytical method used. If your test results have a reference range as follows, you have probably been tested with one of the other test methods
Male Reference Range Test Type
66-417 ng/dL FWRA
12.3-63% %FWRA
5-21 ng/dL UF or ETD
50-210 pg/mL UF or ETD
1.0-2.7% % of free by UF or ETD
Estrogen
Estrogen (measured as estradiol) should be in the mid- to lower-normal range. If estradiol levels are in the upper one-third of the normal reference range, or above the normal reference range, this excessive level of estrogen should be reduced. Labcorp lists a reference range of between 3-70 pg/mL for estradiol while Quest states a reference range of between 10-50. For optimal health, estradiol should be in the range of 10-30 pg/mL for a man of any age.
Total Testosterone
Some men have their total testosterone measured. Standard reference ranges are between 241-827 ng/dL for most laboratories. Many older men are below 241. Optimal levels of total testosterone for most men are between 500-827 ng/dL. If your levels are lower than 500 ng/dL or even a little higher and you still have symptoms, you should check your free testosterone by the Direct (RIA) method.
For other hormone tests, the following are considered to be optimal:
Where You Want to Be
PSA Under 2.6 Standard reference range is up to 4, but if your level is persistently 2.6 or above, have a free PSA test and digital rectal to help rule out prostate cancer.
DHEA 400-560 µg/dL For older men, standard DHEA ranges are very low. It is important for men without prostate cancer to restore them to the youthful range (400-560)
DHT 20-50 ng/dL Reference range is 30-85. DHT is 10 times more androgenic than testosterone and has been implicated in prostate problems and hair loss.
Luteinizing hormone (LH)
If these levels are high, it is an indication of testicular testosterone production deficiency. LH tells the testes to produce testosterone. If there is too little testosterone present, then pituitary gland secretes more LH in a futile effort to stimulate testicular testosterone production. Testosterone replacement therapy should suppress excess LH levels. Low LH can also be a sign of estrogen overload, since too much estrogen can suppress LH activity. This could mean using an estrogen blocker like Arimidex could solve a testosterone deficiency problem.
Age 20-70:
1.5-9.3 mIU/mL
-------------------------------------------------------------------------------- 70+:
3.1-34.6 mIU/mL
Sex Hormone Binding Globulin (SHB6) Reference range is 13-71 nmol/L. Excessive binding inactivates testosterone. (297) 13-55 nmol/L
The fact that most aging men have too much estrogen does not mean it is acceptable for a man to have low estrogen. Estrogen is used by men to maintain bone density, and abnormally low estrogen levels may increase the risk for prostate cancer and osteoporosis (37, 117, 132, 184, 249). The objective is to achieve hormone balance, not to create sky-high testosterone levels without enough estrogen. The problem is that, if we do nothing, most men will have too much estrogen and far too little testosterone.
There are five possible reasons why free testosterone levels may be low-normal (below the upper third of the highest number of the reference range):
Too much testosterone is being converted to estradiol by excess aromatase enzyme and/or the liver is failing to adequately detoxify surplus estrogen. Excess aromatase enzyme and/ or liver dysfunction is likely the cause if estradiol levels are over 30. Remember, aromatase converts testosterone into estradiol, which can cause estrogen overload and testosterone deficiency.
Too much free testosterone is being bound by SHBG (sex hormone-binding globulin) (281-284). This would be especially apparent if total testosterone levels were in the high normal range, while free testosterone was below the upper one-third range.
The pituitary gland fails to secrete adequate amounts of luteinizing hormone (LH) to stimulate testicular production of testosterone. Total testosterone in this case would be in the bottom one-third to one-half range. (On LabCorp's scale, this would be a number below 241 to 500.)
The testes have lost their ability to produce testosterone, despite adequate amounts of the testicular-stimulating luteinizing hormone. In this case, LH would be above normal, and total testosterone would in very low normal or below normal ranges.
Inadequate amounts of DHEA are being produced in the body. (DHEA is a precursor hormone to testosterone and estrogen) (250).
Step 3: What to do when results are less than optimal
If estradiol levels are high (above 30), total testosterone is mid- to high-normal, and free testosterone levels are low or low-normal (at the bottom one third of the highest number on the reference range), you should
Make sure you are getting 80 to 90 mg a day of zinc. (Zinc functions as an aromatase inhibitor for some men.) Consume 110 mg of soy isoflavones (phytoestrogens) each day. (High levels of phytoestrogens compete with estradiol on cell receptor sites and stimulate the liver to remove estrogens from the blood.) Cruciferous vegetables such as broccoli and cauliflower can also stimulate the liver to metabolize and excrete excess estrogen. Reduce or eliminate alcohol consumption to enable your liver to better remove excess estrogens. (Refer to the Foundation's Liver Degeneration protocol to learn about ways to restore healthy liver function.) Review all drugs you are regularly taking to see if they may be interfering with healthy liver function. Common drugs that affect liver function are the NSAIDs: Borage Seed Oil, acetaminophen, aspirin, the "statin" class of cholesterol-lowering drugs, some heart and blood pressure medications, and some antidepressants. It is interesting to note that drugs being prescribed to treat the symptoms of testosterone deficiency such as the statins and certain antidepressants may actually aggravate a testosterone deficit, thus making the cholesterol problem or depression worse. Lose weight. Fat cells, especially in the abdominal region, produce aromatase enzyme, which converts testosterone into estrogen (242).
Take combination supplement providing a flavonoid called chrysin (1000 mg) along with piperine (10 mg) to enable the chrysin to be absorbed into the blood stream. Chrysin has been shown to be a mild aromatase inhibitor. This combination of chrysin and peperine can be found in a product called Super MiraForte.
If all of the above fail to increase free testosterone and lower excess estradiol, ask your doctor to prescribe the potent aromatase inhibiting drug Arimidex (anastrozole) in the very low dose of one-half milligram (0.5 mg), twice a week. Arimidex is prescribed to breast cancer patients at the dose of 1 to 10 mg a day. Even at the higher dose prescribed to cancer patients, side effects are rare. In the minute dose of 0.5 mg twice a week, a man will see an immediate drop in estradiol levels and should experience a rise in free testosterone to the optimal range.
If free testosterone levels are in the lower two thirds of the highest number in the reference range, but total testosterone is high-normal, and estradiol levels are not over 30, you should
Consider following some of the recommendations in the previous section to inhibit aromatase, since many of the same factors are involved in excess SHBG activity. Take 320 mg a day of the super-critical extract of saw palmetto and 240 mg a day of the methanolic extract of nettle (Urtica dioica). Nettle may specifically inhibit SHGB (42-44, 251, 252), while saw palmetto may reduce the effects of excess estrogen by blocking the nuclear estrogen receptor sites in prostate cells, which in turn activate the cell-stimulating effects of testosterone and dihydrotestosterone. Saw palmetto also has the effect of blocking the oxidation of testosterone to androstenedione, a potent androgen that has been implicated in the development of prostate disease (253).
If total testosterone is in the lower one third of the reference range or below normal, and free testosterone is low, you should
See if your luteinizing hormone (LH) is below normal. If LH is low, your doctor can prescribe an individual dose of chorionic gonadotropin (HCG) hormone for injection. Chorionic gonadotropic hormone functions similarly to LH and can re-start testicular production of testosterone. Your doctor can instruct you about how to use tiny 30-gauge needles to give yourself injections two to three times a week.
After 1 month on chorionic gonadotropic hormone, a blood test can determine whether total testosterone levels are significantly increasing. You may also see your testicles growing larger. If total testosterone levels are restored, monitor blood levels of estradiol and free testosterone every 30 to 45 days for the first 5 months to be sure the exogenous testosterone you are using is following a healthy metabolic pathway, i.e., is raising your levels of free testosterone, but not increasing estradiol levels beyond 30.
If total testosterone remains low in spite of several months of chorionic gonadotropic hormone therapy, this indicates that your testicles are not capable of producing testosterone. In that case, initiate therapy with the testosterone patch, pellet, or cream. Do not use testosterone injections or tablets.
Before initiating testosterone replacement therapy, have a PSA blood test and a digital rectal exam to rule out detectable prostate cancer. Once total testosterone levels are restored to a high-normal range, monitor blood levels of estradiol, free testosterone, and PSA every 30 to 45 days for the first 6 months to make sure the exogenous testosterone you are using is following a healthy metabolic pathway and not causing a flare up of an underlying prostate cancer. The objective is to raise your levels of free testosterone to the upper third of the reference range, but to not increase estradiol levels beyond 30.
Excess estrogen (estradiol) blocks the production and effect of testosterone throughout the body, dampens sexuality, and increases the risk of prostate and cardiovascular disease. Once you have established the proper ratio of free testosterone (upper one third of the highest number in the reference range) and estradiol (not more than 30), make sure your blood is tested every 30 to 45 days for the first 5 months. Test every 6 months thereafter for free testosterone, estradiol, and PSA. For men in their 40s to 50s, correcting the excess level of estradiol is often all that has to be done. Men over 60 sometimes need the chorionic gonadotropin injection and may need to use a testosterone patch, cream, or pellet later in life (20).
Therapies
The Testosterone Patch and PSA
An oncologist affiliated with the Life Extension Foundation reports that some men on the testosterone patch will show an elevated PSA that then drops upon cessation of the exogenously administered testosterone. There are published studies that contradict this finding (185, 254-257). Elevation of PSA could be caused by the conversion of exogenous testosterone to estrogen or DHT.
Therapies have been discussed that can prevent testosterone from cascading into estrogen and DHT. This oncologist noted that prostate cancer patients with low testosterone levels have a more aggressive disease, most likely related to the development of tumor cells that are androgen independent and thus more resistant to therapy. This observation is substantiated by the published literature (185, 186, 201, 205, 224-229, 254-256, 286, 288).
Male Hormones and Aging
As men age past year 40, hormonal changes occur that perceptibly inhibit physical, sexual, and cognitive function. The outward appearance of a typical middle-aged male shows increased abdominal fat and shrinkage of muscle mass, a hallmark effect of hormone imbalance. Loss of a feeling of well-being, sometimes manifesting as depression, is a common psychological complication of hormone imbalance (94-97, 271).
Until recently, these changes were attributed to "growing old," and men were expected to accept the fact that their bodies were entering into a long degenerative process that would someday result in death.
A remarkable amount of data has been compiled indicating that many of the diseases that middle-aged men begin experiencing, including depression, fatigue, abdominal weight gain, alterations in mood and cognition, decreased libido, erectile dysfunction, prostate disease, and heart disease, are directly related to hormone imbalances that are correctable with currently available drug and nutrient therapies. These symptoms usually onset around age 40-50, although with smokers the onset is significantly earlier (290-293).
To the patient's detriment, conventional doctors are increasingly prescribing drugs to treat depression, elevated cholesterol, angina, and a host of other diseases that might be caused by an underlying hormone imbalance.
If doctors checked their male patients' blood levels of estrogen, testosterone, thyroid, and DHEA (instead of prescribing drugs to treat symptoms), they might be surprised to learn that many problems could be eliminated by adjusting hormone levels to fit the profile of a healthy 21-year-old male.
Few physicians are familiar with the hormone blood tests that should be ordered for men, nor do they have the experience required to properly adjust hormones to reverse the degenerative changes that begin in mid-life. This protocol will provide the patient and physician with the information necessary to safely modulate hormone levels for the purpose of preventing and treating many of the common diseases associated with growing older.
Too Much Estrogen
The most significant hormone imbalance in aging men is a decrease in free testosterone, while estrogen levels remain the same or increase precipitously. As men grow older, they experience a variety of mechanisms from the dual effects of having too little testosterone and excess estrogen. The result is a testosterone-estrogen imbalance that directly causes many of the debilitating health problems associated with normal aging (1-12, 28).
One cause of hormone imbalance in men is that their testosterone is increasingly converted to estrogen. One report showed that estrogen levels of the average 54-year-old man are higher than those of the average 59-year-old woman (1, 5, 13-18, 48).
The reason that testosterone replacement therapy does not work by itself for many men is that exogenously administered testosterone may convert (aromatize) into even more estrogen, thus potentially worsening the hormone imbalance problem in aging males (i.e., too much estrogen and not enough free testosterone) (21, 26). While there are studies showing that testosterone replacement therapy does not increase estrogen beyond normal reference ranges, we will show later how the standard laboratory reference ranges do not adequately address the issue of estrogen overload (4, 8, 9, 17, 22-25, 27, 29-32).
Estrogen is an essential hormone for men, but too much of it causes a wide range of health problems. The most dangerous acute effect of excess estrogen and too little testosterone is an increased risk of heart attack or stroke (39-43, 261-270). High levels of estrogen have been implicated as a cause of benign prostatic hypertrophy (prostate enlargement) (35-44, 46, 47). One mechanism by which nettle root extract works is to block the binding of growth-stimulating estrogen to prostate cells (42-44, 48-50).
When there is too little testosterone present, estrogen attaches to testosterone cell receptor sites throughout the body and creates many problems in aging men. In youth, low amounts of estrogen are used to turn off the powerful cell-stimulating effects of testosterone. As estrogen levels increase with age, testosterone cell stimulation may be locked in the "off" position, thus reducing sexual arousal and sensation and causing the loss of libido so common in aging men (94, 99, 259).
High serum levels of estrogen also trick the brain into thinking that enough testosterone is being produced, further slowing the natural production of testosterone. This happens when estrogen saturates testosterone receptors in the hypothalamus region of the brain. The saturated hypothalamus then stops sending out a hormone to the pituitary gland to stimulate secretion of luteinizing hormone that the gonads require to produce testosterone. High estrogen can thus shut down the normal testicular production of testosterone (1, 53, 54, 271-277).
One further complication of excess estrogen is that it increases the body's production of sex hormone-binding globulin (SHBG) (280). SHBG binds free testosterone in the blood and makes it unavailable to cell receptor sites (51, 52, 55, 56).
Based on the multiple deleterious effects of excess estrogen in men, aggressive action should be taken to reduce estrogen to a safe range if a blood test reveals elevated levels. We will discuss the appropriate blood tests and steps that can be taken to lower estrogen levels later in this protocol.
The Critical Importance of Free Testosterone
Testosterone is much more than a sex hormone. There are testosterone receptor sites in cells throughout the body, most notably in the brain and heart (60, 180). Youthful protein synthesis for maintaining muscle mass and bone formation requires testosterone (57, 59, 61-74, 87-90, 261- 264, 287). Testosterone improves oxygen uptake throughout the body, helps control blood sugar (68, 75-80), regulates cholesterol (67, 69, 81), and maintains immune surveillance (82, 83). The body requires testosterone to maintain youthful cardiac output and neurological function (58, 65). Testosterone is also a critical hormone in the maintenance of healthy bone density (59, 66, 67, 84-86), muscle mass (65-67, 87-90, 287), and red blood cell production (67, 69, 91-93, 98).
Of critical concern to psychiatrists are studies showing that men with depression have lower levels of testosterone than do control subjects (94-98). For some men, elevating free testosterone levels could prove to be an effective antidepressant therapy. There is a basis for free testosterone levels being measured in men with depression and for replacement therapy being initiated if free testosterone levels are low normal or below normal.
Testosterone is one of the most misunderstood hormones. Body builders tarnished the reputation of testosterone by putting large amounts of synthetic testosterone drugs into their young bodies. Synthetic testosterone abuse can produce detrimental effects (34), but this has nothing to do with the benefits a man over age 40 can enjoy by properly restoring his natural testosterone to a youthful level.
Conventional doctors have not recommended testosterone replacement therapy because of an erroneous concern that testosterone causes prostate cancer. As we will later show, fear of prostate cancer is not a scientifically valid reason to avoid testosterone modulation therapy.
Another concern that skeptical physicians have about prescribing testosterone replacement therapy is that some poorly conducted studies showed it to be ineffective in the long-term treatment of aging. These studies indicate anti-aging benefits when testosterone is given, but the effects often wear off. What physicians fail to appreciate is that exogenously administered testosterone can convert to estrogen in the body. The higher estrogen levels may negate the benefits of the exogenously administered testosterone. The solution to the estrogen-overload problem is to block the conversion of testosterone to estrogen in the body. Numerous studies show that maintaining youthful levels of free testosterone can enable the aging man to restore strength, stamina, cognition, heart function, sexuality, and outlook on life, i.e., to alleviate depression (261-270). A study in Drugs and Aging (1999) suggested that androgen therapy can result in polycythemia (increased numbers of red blood cells) causing an increase in blood viscosity and risk of clotting (303). For many aging men, however, borderline anemia is a greater concern than red blood cell overproduction. When men are deprived of testosterone during prostate cancer therapy, anemia frequently manifests. Life Extension has not seen cases of polycythemia in men replacing testosterone to physiological youthful ranges. In other words, too much testosterone could cause problems, but replacing testosterone to that of a healthy 21-year-old should not produce the side effects that some doctors are unduly concerned about. As you will read in the section entitled "Testosterone and the Heart," it appears that testosterone replacement therapy provides significant beneficial effects against cardiovascular disease.
Why Testosterone Levels Decline
Testosterone production begins in the brain. When the hypothalamus detects a deficiency of testosterone in the blood, it secretes a hormone called gonadotrophin-releasing hormone to the pituitary gland. This prompts the pituitary to secrete luteinizing hormone (LH), which then prompts the Leydig cells in the testes to produce testosterone.
In some men, the testes lose their ability to produce testosterone, no matter how much LH is being produced. This type of testosterone deficiency is diagnosed when blood tests show high levels of LH and low levels of testosterone. In other words, the pituitary gland is telling the testes (by secreting LH) to produce testosterone, but the testes have lost their functional ability. So the pituitary gland vainly continues to secrete LH because there is not enough testosterone in the blood to provide a feedback mechanism that would tell the pituitary to shut down. In other cases, the hypothalamus, or pituitary gland, fails to produce sufficient amounts of LH, thus preventing healthy testes from secreting testosterone. Blood testing can determine whether sufficient amounts of LH are being secreted by the pituitary gland and help determine the appropriate therapeutic approach. If serum (blood) testosterone levels are very low, it is important to diagnose the cause, but no matter what the underlying problem, therapies exist today to safely restore testosterone to youthful levels in any man (who does not already have prostate cancer).
As indicated earlier, a major problem that aging men face is not low production of testosterone, but excessive conversion of testosterone to estrogen. Specific therapies to suppress excess estrogen and boost free testosterone back to youthful physiological levels will be discussed later.
Source: Courtesy of Stephen Strum, M.D.
The Effects of Testosterone on Libido
Sexual stimulation and erection begin in the brain when neuronal testosterone-receptor sites are prompted to ignite a cascade of biochemical events that involve testosterone-receptor sites in the nerves, blood vessels, and muscles. Free testosterone promotes sexual desire and then facilitates performance, sensation, and the ultimate degree of fulfillment.
Without adequate levels of free testosterone, the quality of a man's sex life is adversely affected and the genitals atrophy. When free testosterone is restored, positive changes can be expected in the structure and function of the sex organs. (It should be noted that sexual dysfunction can be caused by other factors unrelated to hormone imbalance. An example of such a factor is arteriosclerotic blockage of the penile arteries.)
The genital-pelvic region is packed with testosterone receptors that are ultra-sensitive to free testosterone-induced sexual stimulation. Clinical studies using testosterone injections, creams, or patches have often failed to provide a long-lasting, libido-enhancing effect in aging men (98). We now know why. The testosterone can be converted to estrogen. The estrogen is then taken up by testosterone receptor sites in cells throughout the body. When an estrogen molecule occupies a testosterone receptor site on a cell membrane, it blocks the ability of serum testosterone to induce a healthy hormonal signal. It does not matter how much serum free testosterone is available if excess estrogen is competing for the same cellular receptor sites.
Estrogen can also increase the production of sex hormone-binding globulin (SHBG), which binds the active free testosterone into an inactive "bound testosterone." Bound testosterone cannot be picked up by testosterone receptors on cell membranes. For testosterone to produce long-lasting, libido-enhancing effects, it must be kept in the "free" form (not bound to SHBG) in the bloodstream. It is also necessary to suppress excess estrogen because this hormone can compete for testosterone receptor sites in the sex centers of the brain and the genitals.
Restoring youthful hormone balance can have a significant impact on male sexuality (99-102).
Testosterone and the Heart
Normal aging results in the gradual weakening of the heart, even in the absence of significant coronary artery disease. If nothing else kills the elderly male, his heart just stops beating at some point.
Testosterone is a muscle-building hormone, and there are many testosterone-receptor sites in the heart (57). The weakening of the heart muscle can sometimes be attributed to testosterone deficiency (103-108). Testosterone is not only responsible for maintaining heart muscle protein synthesis, it is also a promoter of coronary artery dilation (109-113) and helps to maintain healthy cholesterol levels (81, 114).
There are an ever-increasing number of studies indicating an association between high testosterone and low cardiovascular disease rates in men (81). In the majority of patients, symptoms and EKG measurements improve when low testosterone levels are corrected. One study showed that blood flow to the heart improved 68.8% in those receiving testosterone therapy (9). In China, doctors are successfully treating angina with testosterone therapy (9, 115, 116).
The following list represents the effects of low testosterone on cardiovascular disease:
Cholesterol, fibrinogen, triglycerides, and insulin levels increase (30-33).
Coronary artery elasticity diminishes.
Blood pressure rises.
Human growth hormone (HGH) declines (weakening heart muscle).
Abdominal fat increases (increasing the risk of heart attack).
Those with cardiovascular disease should have their blood tested for free testosterone and estrogen. Some men (with full cooperation from their physicians) may be able to stop taking expensive drugs to stimulate cardiac output, lower cholesterol, and keep blood pressure under control, if they correct a testosterone deficit or a testosterone-estrogen imbalance. Recently, a compelling study of 1100 men showed that those with serum DHEA-S in the lowest quarter (<1.6 µg/mL) were significantly more likely to incur symptoms of heart disease (295), and in a review of several studies, other authors have confirmed this association (296). DHEA is produced by the adrenal gland and is a precursor hormone for the manufacture of testosterone. (See the DHEA and Pregnenolone Precautions protocol.)
Despite numerous studies substantiating the beneficial effects of testosterone therapy in treating heart disease, conventional cardiologists continue to overlook the important role this hormone plays in keeping their cardiac patients alive (9, 30, 31, 77, 93, 111-113, 115, 116, 261-270).
Testosterone and the Prostate Gland
Many doctors will tell you that testosterone causes prostate disease. The published scientific literature indicates otherwise.
As readers of Life Extension Magazine learned in late 1997, estrogen has been identified as a primary culprit in the development of benign prostate hypertrophy (prostate enlargement) (117-119). Estrogen has been shown to bind to SHBG in the prostate gland and cause the proliferation of epithelial cells in the prostate (124, 182-184). This is corroborated by the fact that as men develop benign prostate enlargement, their levels of free testosterone plummet, while their estrogen levels remain the same or are rising. As previously discussed, aging men tend to convert their testosterone into estrogen. The published evidence shows that serum levels of testosterone are not a risk factor for developing benign prostate disease (8, 36, 41, 117-137).
The major concern that has kept men from restoring their testosterone to youthful levels is fear of prostate cancer. The theory is that since most prostate cancer cell lines need testosterone to proliferate, it is better not to replace the testosterone that is lost with aging. The problem with this theory is that most men who develop prostate cancer have low levels of testosterone, and the majority of published studies show that serum testosterone levels do not affect one's risk for contracting prostate cancer.
Since there is such a strong perception that any augmentation of testosterone can increase the risk of prostate cancer, we did a MEDLINE search on all the published studies relating to serum testosterone and prostate cancer. The abstracts at the end of this protocol provide quotations from the published literature as it relates to the issue of whether testosterone causes prostate disease. Of the 27 MEDLINE studies found, 5 studies indicated that men with higher testosterone levels had a greater incidence of prostate cancer, whereas 21 studies showed that testosterone was not a risk factor and 1 study was considered neutral.
Before starting a testosterone replacement program, men should have a serum PSA test and a digital rectal exam to rule out prostate cancer. Nothing is risk free. A small minority of men with low testosterone and prostate cancer will not have an elevated PSA or palpable lesion detectable by digital rectal exam. If these men use supplemental testosterone, they risk an acute flare-up in their disease state. That is why PSA monitoring is so important every 30 to 45 days during the first 6 months of any type of testosterone augmentation therapy. If an underlying prostate cancer is detected because of testosterone therapy, it is usually treatable by non-surgical means.
Please remember that testosterone does not cause acute prostate cancer, but if you have existing prostate cancer and do not know it, testosterone administration is likely to boost PSA sharply and provide your doctor with a quick diagnosis of prostate cancer (and an opportunity for very early treatment). We acknowledge that some aging men will not want to take this risk.
As stated above, the MEDLINE score was 21 to 5 against the theory that testosterone plays a role in the development of prostate cancer. None of these studies took into account the prostate cancer prevention effects for men who take lycopene, selenium, and vitamins A and E (135-144), nor did they factor in possible prostate disease preventives such as saw palmetto, nettle, soy, and pygeum (42-44, 145-170, 172).
In Dr. Jonathan Wright's book, Maximize Your Vitality & Potency, a persuasive case is made that testosterone and DHEA actually protect against the development of both benign and malignant prostate disease (305). Dr. Wright also points out that natural therapies such as saw palmetto, nettle, and pygeum provide a considerable degree of protection against the alleged negative effects that higher levels of testosterone might have on the prostate gland.
We eagerly await the results of more studies, but the fear of developing prostate cancer in the future should not be a reason to deprive your body today of the life-saving and life-enhancing benefits of restoring a youthful hormone balance.
Once a man has prostate cancer, testosterone therapy cannot be recommended because most prostate cancer cells use testosterone as a growth promoter. Regrettably, this denies prostate cancer patients the wonderful benefits of testosterone therapy. Men with severe benign prostatic hyperplasia (prostate enlargement) should approach testosterone replacement cautiously. It would be prudent for those with prostate enlargement who are taking testosterone replacement therapy to also use the drug Proscar (finasteride) to inhibit 5-alpha-reductase levels, thereby suppressing the formation of dihydrotestosterone (DHT) (171-182). DHT is ten times more potent than testosterone in promoting prostate growth, and suppressing DHT is a proven therapy in treating benign prostate enlargement. Saw palmetto extract suppresses some DHT in the prostate gland, but saw palmetto's effectiveness in alleviating symptoms of prostate enlargement probably has more to do with
Its blocking of alpha-adrenergic receptor sites on the sphincter muscle surrounding the urethra. (This is how the drug Hytrin works.)
Its inhibition of estrogen binding to prostate cells (such as nettle).
Its inhibition of the enzyme 3-ketosteroid (which causes the binding of DHT to prostate cells).
Its anti-inflammatory effect on the prostate.
Note: Men with severe prostate enlargement may also consider using the drug Arimidex (0.5 mg, twice a week) to suppress excess levels of estrogen. Estrogen can worsen prostate enlargement and supplemental testosterone can elevate estrogen if an aromatase-inhibiting drug such as Arimidex is not used.
It is unfortunate that many people still think that restoring testosterone to youthful levels will increase the risk of prostate disease. This misconception has kept many men from availing themselves of this life-enhancing and life-saving hormone.
While it is clear that excess estrogen causes benign prostate enlargement, the evidence for excess estrogen's role in the development of prostate cancer is uncertain (8, 41, 117-134, 182-217, 236). Some studies show that elevated estrogen is associated with increased prostate cancer risk, while other studies contradict this finding. For more information on testosterone, estrogen, and the prostate gland, refer to the February 1999 issue of Life Extension Magazine (182-217, 306).
Correcting a Hormone Imbalance
A male hormone imbalance can be detected through use of the proper blood tests and can be corrected using available drugs and nutrients. The following represents a step-by-step program to safely restore youthful hormone balance in aging men:
Step 1: Blood testing
The following initial blood tests are recommended for any man over age 40:
Complete blood count and chemistry profile to include liver-kidney function, glucose, minerals, lipids, and thyroid (TSH) Free and Total Testosterone
Estradiol (estrogen)
DHT (dihydrotestosterone)
DHEA
PSA
Homocysteine
Luteinizing hormone (LH) (optional)
Sex Hormone Binding Globulin (SHBG) optional
Step 2: Interpretation of free testosterone, estrogen, and total testosterone blood test results
One can easily determine if they need testosterone replacement or estrogen suppression by adhering to the following guidelines:
Free testosterone
Free testosterone blood levels should be at the high-normal of the reference range. We define high-normal range as the upper one third of the reference range. Under no circumstances should free or total testosterone be above the high end of the normal range.
What too often happens is that a standard laboratory "reference range" deceives a man (and his physician) into believing that proper hormone balance exists because the results of a free testosterone test fall within the "normal" range. The following charts show a wide range of so-called "normal" ranges of testosterone for men of various ages. While these normal ranges may reflect population "averages," the objective for most men over age 40 is to be in the upper one-third testosterone range of the 21- to 29-year-old group. Based on the following reference range chart from LabCorp, this means that optimal free testosterone levels should be between 21-26.5 ng/dL in aging men.
Reference Intervals for Free Testosterone from LabCorp
20-29 years 9.3-26.5 pg/mL
30-39 years 8.7-25.1 pg/mL
40-49 years 6.8-21.5 pg/mL
50-59 years 7.2-24.0 pg/mL
60+ years 6.6-18.1 pg/mL
An example of how this chart can be deceptive would be if a 50-year-old man presented with symptoms of testosterone deficiency (depression, low energy, abdominal obesity, angina, etc.), but his blood test revealed his free testosterone to be 9 pg/mL. His doctor might tell him he is fine because he falls within the normal "reference range." The reality may be that to achieve optimal benefits, testosterone levels should be between 21-26.5 pg/mL. That means a man could have less than half the amount of testosterone needed to overcome symptoms of a testosterone deficiency, but his doctor will not prescribe testosterone replacement because the man falls within the "average" parameters. That is why it is so important to differentiate between "average" and "optimal." Average 50-year-old men often have the symptoms of having too little testosterone. Yet since so many 50-year-old men have lower than desired testosterone levels, this is considered to be "normal" when it comes to standard laboratory reference ranges.
The Life Extension Foundation would like to point out that there is disagreement between clinicians and laboratories on the best method for measuring testosterone status. There are different schools of thought as to which form of testosterone should be measured and which analytical procedure provides the most accurate assessment of metabolic activity. We believe that direct testing for free testosterone is the best way to test for testosterone activity, as free testosterone is active testosterone and consists of only 1-2% of total testosterone. Total testosterone can be good for general testing. The four main methods presently used for analyzing free testosterone are:
Direct, Free Testosterone by Direct Analog/Radioimmunoassay (RIA) Testosterone Free by Ultrafiltration (UF)
Testosterone Free by Equilibrium Tracer Dialysis (ETD)
Testosterone Free and Weakly Bound by Radioasssay (FWRA)
The latter three test methods are older, more complicated methods that are technically demanding. The direct RIA test has a number of commercial test kits available, and they are better used in today's automated equipment, making this test less tedious and requiring a smaller (less) sample. These advantages have convinced many laboratories and clinics to prefer direct RIA testing for Free Testosterone. The Life Extension Foundation agrees with this assessment, and therefore uses and recommends the Direct, Free Testosterone test with the above-mentioned reference levels.
Consequently, if your doctor tests your free testosterone, be sure you know the analytical method used. If your test results have a reference range as follows, you have probably been tested with one of the other test methods
Male Reference Range Test Type
66-417 ng/dL FWRA
12.3-63% %FWRA
5-21 ng/dL UF or ETD
50-210 pg/mL UF or ETD
1.0-2.7% % of free by UF or ETD
Estrogen
Estrogen (measured as estradiol) should be in the mid- to lower-normal range. If estradiol levels are in the upper one-third of the normal reference range, or above the normal reference range, this excessive level of estrogen should be reduced. Labcorp lists a reference range of between 3-70 pg/mL for estradiol while Quest states a reference range of between 10-50. For optimal health, estradiol should be in the range of 10-30 pg/mL for a man of any age.
Total Testosterone
Some men have their total testosterone measured. Standard reference ranges are between 241-827 ng/dL for most laboratories. Many older men are below 241. Optimal levels of total testosterone for most men are between 500-827 ng/dL. If your levels are lower than 500 ng/dL or even a little higher and you still have symptoms, you should check your free testosterone by the Direct (RIA) method.
For other hormone tests, the following are considered to be optimal:
Where You Want to Be
PSA Under 2.6 Standard reference range is up to 4, but if your level is persistently 2.6 or above, have a free PSA test and digital rectal to help rule out prostate cancer.
DHEA 400-560 µg/dL For older men, standard DHEA ranges are very low. It is important for men without prostate cancer to restore them to the youthful range (400-560)
DHT 20-50 ng/dL Reference range is 30-85. DHT is 10 times more androgenic than testosterone and has been implicated in prostate problems and hair loss.
Luteinizing hormone (LH)
If these levels are high, it is an indication of testicular testosterone production deficiency. LH tells the testes to produce testosterone. If there is too little testosterone present, then pituitary gland secretes more LH in a futile effort to stimulate testicular testosterone production. Testosterone replacement therapy should suppress excess LH levels. Low LH can also be a sign of estrogen overload, since too much estrogen can suppress LH activity. This could mean using an estrogen blocker like Arimidex could solve a testosterone deficiency problem.
Age 20-70:
1.5-9.3 mIU/mL
-------------------------------------------------------------------------------- 70+:
3.1-34.6 mIU/mL
Sex Hormone Binding Globulin (SHB6) Reference range is 13-71 nmol/L. Excessive binding inactivates testosterone. (297) 13-55 nmol/L
The fact that most aging men have too much estrogen does not mean it is acceptable for a man to have low estrogen. Estrogen is used by men to maintain bone density, and abnormally low estrogen levels may increase the risk for prostate cancer and osteoporosis (37, 117, 132, 184, 249). The objective is to achieve hormone balance, not to create sky-high testosterone levels without enough estrogen. The problem is that, if we do nothing, most men will have too much estrogen and far too little testosterone.
There are five possible reasons why free testosterone levels may be low-normal (below the upper third of the highest number of the reference range):
Too much testosterone is being converted to estradiol by excess aromatase enzyme and/or the liver is failing to adequately detoxify surplus estrogen. Excess aromatase enzyme and/ or liver dysfunction is likely the cause if estradiol levels are over 30. Remember, aromatase converts testosterone into estradiol, which can cause estrogen overload and testosterone deficiency.
Too much free testosterone is being bound by SHBG (sex hormone-binding globulin) (281-284). This would be especially apparent if total testosterone levels were in the high normal range, while free testosterone was below the upper one-third range.
The pituitary gland fails to secrete adequate amounts of luteinizing hormone (LH) to stimulate testicular production of testosterone. Total testosterone in this case would be in the bottom one-third to one-half range. (On LabCorp's scale, this would be a number below 241 to 500.)
The testes have lost their ability to produce testosterone, despite adequate amounts of the testicular-stimulating luteinizing hormone. In this case, LH would be above normal, and total testosterone would in very low normal or below normal ranges.
Inadequate amounts of DHEA are being produced in the body. (DHEA is a precursor hormone to testosterone and estrogen) (250).
Step 3: What to do when results are less than optimal
If estradiol levels are high (above 30), total testosterone is mid- to high-normal, and free testosterone levels are low or low-normal (at the bottom one third of the highest number on the reference range), you should
Make sure you are getting 80 to 90 mg a day of zinc. (Zinc functions as an aromatase inhibitor for some men.) Consume 110 mg of soy isoflavones (phytoestrogens) each day. (High levels of phytoestrogens compete with estradiol on cell receptor sites and stimulate the liver to remove estrogens from the blood.) Cruciferous vegetables such as broccoli and cauliflower can also stimulate the liver to metabolize and excrete excess estrogen. Reduce or eliminate alcohol consumption to enable your liver to better remove excess estrogens. (Refer to the Foundation's Liver Degeneration protocol to learn about ways to restore healthy liver function.) Review all drugs you are regularly taking to see if they may be interfering with healthy liver function. Common drugs that affect liver function are the NSAIDs: Borage Seed Oil, acetaminophen, aspirin, the "statin" class of cholesterol-lowering drugs, some heart and blood pressure medications, and some antidepressants. It is interesting to note that drugs being prescribed to treat the symptoms of testosterone deficiency such as the statins and certain antidepressants may actually aggravate a testosterone deficit, thus making the cholesterol problem or depression worse. Lose weight. Fat cells, especially in the abdominal region, produce aromatase enzyme, which converts testosterone into estrogen (242).
Take combination supplement providing a flavonoid called chrysin (1000 mg) along with piperine (10 mg) to enable the chrysin to be absorbed into the blood stream. Chrysin has been shown to be a mild aromatase inhibitor. This combination of chrysin and peperine can be found in a product called Super MiraForte.
If all of the above fail to increase free testosterone and lower excess estradiol, ask your doctor to prescribe the potent aromatase inhibiting drug Arimidex (anastrozole) in the very low dose of one-half milligram (0.5 mg), twice a week. Arimidex is prescribed to breast cancer patients at the dose of 1 to 10 mg a day. Even at the higher dose prescribed to cancer patients, side effects are rare. In the minute dose of 0.5 mg twice a week, a man will see an immediate drop in estradiol levels and should experience a rise in free testosterone to the optimal range.
If free testosterone levels are in the lower two thirds of the highest number in the reference range, but total testosterone is high-normal, and estradiol levels are not over 30, you should
Consider following some of the recommendations in the previous section to inhibit aromatase, since many of the same factors are involved in excess SHBG activity. Take 320 mg a day of the super-critical extract of saw palmetto and 240 mg a day of the methanolic extract of nettle (Urtica dioica). Nettle may specifically inhibit SHGB (42-44, 251, 252), while saw palmetto may reduce the effects of excess estrogen by blocking the nuclear estrogen receptor sites in prostate cells, which in turn activate the cell-stimulating effects of testosterone and dihydrotestosterone. Saw palmetto also has the effect of blocking the oxidation of testosterone to androstenedione, a potent androgen that has been implicated in the development of prostate disease (253).
If total testosterone is in the lower one third of the reference range or below normal, and free testosterone is low, you should
See if your luteinizing hormone (LH) is below normal. If LH is low, your doctor can prescribe an individual dose of chorionic gonadotropin (HCG) hormone for injection. Chorionic gonadotropic hormone functions similarly to LH and can re-start testicular production of testosterone. Your doctor can instruct you about how to use tiny 30-gauge needles to give yourself injections two to three times a week.
After 1 month on chorionic gonadotropic hormone, a blood test can determine whether total testosterone levels are significantly increasing. You may also see your testicles growing larger. If total testosterone levels are restored, monitor blood levels of estradiol and free testosterone every 30 to 45 days for the first 5 months to be sure the exogenous testosterone you are using is following a healthy metabolic pathway, i.e., is raising your levels of free testosterone, but not increasing estradiol levels beyond 30.
If total testosterone remains low in spite of several months of chorionic gonadotropic hormone therapy, this indicates that your testicles are not capable of producing testosterone. In that case, initiate therapy with the testosterone patch, pellet, or cream. Do not use testosterone injections or tablets.
Before initiating testosterone replacement therapy, have a PSA blood test and a digital rectal exam to rule out detectable prostate cancer. Once total testosterone levels are restored to a high-normal range, monitor blood levels of estradiol, free testosterone, and PSA every 30 to 45 days for the first 6 months to make sure the exogenous testosterone you are using is following a healthy metabolic pathway and not causing a flare up of an underlying prostate cancer. The objective is to raise your levels of free testosterone to the upper third of the reference range, but to not increase estradiol levels beyond 30.
Excess estrogen (estradiol) blocks the production and effect of testosterone throughout the body, dampens sexuality, and increases the risk of prostate and cardiovascular disease. Once you have established the proper ratio of free testosterone (upper one third of the highest number in the reference range) and estradiol (not more than 30), make sure your blood is tested every 30 to 45 days for the first 5 months. Test every 6 months thereafter for free testosterone, estradiol, and PSA. For men in their 40s to 50s, correcting the excess level of estradiol is often all that has to be done. Men over 60 sometimes need the chorionic gonadotropin injection and may need to use a testosterone patch, cream, or pellet later in life (20).
Therapies
The Testosterone Patch and PSA
An oncologist affiliated with the Life Extension Foundation reports that some men on the testosterone patch will show an elevated PSA that then drops upon cessation of the exogenously administered testosterone. There are published studies that contradict this finding (185, 254-257). Elevation of PSA could be caused by the conversion of exogenous testosterone to estrogen or DHT.
Therapies have been discussed that can prevent testosterone from cascading into estrogen and DHT. This oncologist noted that prostate cancer patients with low testosterone levels have a more aggressive disease, most likely related to the development of tumor cells that are androgen independent and thus more resistant to therapy. This observation is substantiated by the published literature (185, 186, 201, 205, 224-229, 254-256, 286, 288).