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III. Which Testosterone Assay Should Be Used In Older Men?¹

Veterans Affairs HCSPS and Geriatric Research Education and Clinical Center University of Washington School of Medicine Seattle, Washington 98195

	Introduction

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IN WOMEN, the determination of age-associated gonadal failure is usually signaled as ovulation ceases with the cessation of the menstruation. A decrease in estrogen production after menopause is also evident by the onset of physical symptoms such as hot flushes, dry vagina, etc. that are easily discerned by the woman. However, measurement of estrogen levels during the follicular phase of the menstrual cycle preceding menopause and again after menopause does not necessarily reflect the magnitude of menopausal symptoms or marked increase in gonadotropins.

The determination of age-associated hypogonadism (so-called andropause) is not as clear in men as it is in women. It is possible that andropause may not even occur in the majority of men, if it exists at all, as an independent entity outside of a disease-associated decline in plasma concentrations of testosterone. As men age, there is a decline in serum total testosterone levels that begins about the age of 40 yr. In cross-sectional studies the annual decline in total and "free" testosterone is 0.4% and 1.2%, respectively (1). However, it should be noted that these studies are cross-sectional, and although the serum testosterone level declines with age, the mean value for a group of disease-free men is rarely below the lower limits of the normal range for most laboratories, even into the ninth decade of life (2). The diagnosis of an andropause in an individual man is not necessarily further substantiated by the measurement of serum gonadotropins. In men, careful measurements of luteinizing hormone (LH) and FSH made in pooled blood samples reveals a small but significant increase in serum gonadotropin levels (3, 4, 5). However, unlike in women, the increase in blood gonadotropin levels in older, otherwise healthy men is not above the normal range for healthy adult men.

Testosterone circulates in the blood 98% bound to protein. In men, approximately 40% of the binding is to the high affinity sex hormone binding globulin (SHBG), association constant (Ka) 1 x 10⁹ L/mol, and approximately 60% bound weakly to albumin (Ka = 3 x 10⁴ L/mol) (6, 7). A number of measurements for testosterone are available from clinical laboratories, and it is important to understand the differences among them (7, 8, 9, 10, 11). The measurement of serum testosterone or "total" testosterone is usually performed by a radioimmunoassay and measures free plus protein bound testosterone. "Free" or dialyzable testosterone measurements are estimates of the fraction of testosterone in blood that is not bound to protein. These assays require determination of the percentage of unbound testosterone by a dialysis procedure, estimation of total testosterone, and the calculation of free testosterone. Free testosterone can also be calculated if total testosterone, SHBG, and albumin concentrations are known (8). Kits are available for determination of free testosterone without dialysis and are used to provide a free testosterone measurement by many laboratories. Unfortunately, these measurements are often inaccurate, especially when the testosterone levels are low and SHBG levels are elevated (9, 12). A third measurement of testosterone commonly made is that of "bioavailable" or non-SHBG bound testosterone (10). This measurement determines the amount of testosterone not bound to SHBG and includes that which is nonprotein bound and weakly bound to albumin. It is this fraction that supposedly is "bioavailable" to tissues. This measurement takes into account that SHBG is precipitated by a lower concentration of ammonium sulfate, 50%, than albumin. Thus by precipitating a serum sample with 50% ammonium sulfate and measuring the testosterone value in the supernate, non-SHBG bound or bioavailable testosterone is measured. This fraction of testosterone can also be calculated if total testosterone, SHBG, and albumin levels are known.

To evaluate the clinical utility of serum testosterone measurements, it is important to identify whether or not the normal laboratory range for testosterone is valid in the older man, or if there are changes in testosterone dynamics with age that may affect interpretation of testosterone levels. Serum testosterone levels begin to decline in normal healthy men on no medications, in the mid- to late-thirties. This decline is linear into the nineties, at a rate of 0.4%/year. If men with chronic medical illnesses are evaluated (illness defined as hypertension, heart disease, diabetes, but not a hospitalized patient), it appears that the same age-associated decline in serum testosterone occurs, but that at any age the level for a man with a chronic illness is 10–15% below that of healthy age-matched men. In addition to this decline with age in total testosterone, there is an associated increase in sex hormone binding globulin (SHBG), the circulating high affinity binding protein for testosterone (2, 5, 13). Therefore, as man ages, the total testosterone level decreases, but the serum binding of testosterone increases. This increase in testosterone binding results in a "free" or bioavailable testosterone level that decreases to a greater extent than total testosterone. As a result, the availability of the free active form of testosterone in the serum is further reduced compared with total testosterone. Clinically, free T is decreased with age to a greater extent than total T. However, it is unclear whether free T is the only bioavailable fraction of testosterone for most of the tissues. Using various model systems and depending on the tissue and rate of blood flow through the tissue, the total concentration of circulating testosterone available to the organs can be calculated (6). The problem arises when studies attempt to determine whether certain age- and gender-associated problems, such as impotence, are better correlated with measurements of free or bioavailable testosterone than total testosterone (10). However, when men with impotence and low levels of bioavailable testosterone receive testosterone replacement therapy, there is no greater improvement in their impotence compared with similarly treated impotent men with normal levels of testosterone (14). Thus, although bioavailable and free testosterone measurements are lower in men with possible androgen related symptoms, they apparently do not respond to androgen replacement. These data point to two problems, 1) symptoms that we may feel are androgen related are probably multifactorial and not reliable measures of androgen action. Secondly, the measurement of testosterone that relies on an assessment of protein-bound T may not be a reflection of a deficiency of T, but may be the result of a change in the binding protein by a problem independent of the androgen state of the man. For example, a decrease in SHBG may occur in type II diabetes mellitus as a result of an increase in insulin or insulin-like growth factor I levels (15, 16). This reduction in SHBG level, unrelated to androgen deficiency and associated with decreased total androgen in diabetic patients, may be coincidentally related to impotence, when in fact, the impotence is due to diabetes mellitus. Clinical situations such as these, point out the difficulty in assessing androgen status when there is no good independent marker of androgen action that can be used in vivo. In addition, there are no well designed clinical trials that have indicated that one method of testosterone measurement is better than any another at defining a group of men who are androgen deficient and will respond to testosterone replacement therapy. Therefore, either until appropriate clinical studies are published or until a good marker of testosterone action becomes available, a total serum testosterone is as good a measurement, and less expensive, than a more complex and labor intensive measure of free or bioavailable testosterone. In addition, one must be aware that assays that purport to measure free testosterone without using a dialysis method or without calculating free testosterone levels based on separate measurements of testosterone and SHBG, can markedly underestimate by as much as 100% the true free hormone level (9). This sort of assay error can result in an incorrect overestimation of the degree or prevalence of androgen deficiency.

An additional factor that needs to be taken into account when looking at the differences in testosterone levels between young and elderly men, is the difference in circadian variation. Young men clearly have a circadian rhythm of testosterone, with the zenith in the morning between 0600 h and 0800 h and the nadir in the late afternoon between 1700 h and 1800 h (5, 17). In elderly men, the circadian rhythm, if detected, is much flatter and tends not to be consistent between individuals. Clinically, this means that the difference in blood testosterone levels between young and elderly men can be readily detected when measurements are made in the morning during the zenith of the testosterone rhythm, but the difference may be lost if samples are collected in the late afternoon. However, even though the difference in testosterone secretory patterns is clearly altered between young and elderly men, the clinical significance of this altered secretory pattern has not yet been determined. With the development of testosterone delivery systems that can mimic the circadian variation in testosterone secretion, clinical studies may be designed that can address the biological significance of the circadian variation in testosterone.

In summary, based on the data currently available, the measurement of total blood testosterone is the most appropriate test to determine whether an older individual is hypogonadal or not. If the total testosterone level is less than 7.0 nm/L (2 ng/mL), the individual should be considered hypogonadal and, regardless of age, further evaluation should be the same as for any other hypogonadal individual. The question that cannot be answered with our present data base, however, is whether or not otherwise healthy men or those with chronic illnesses with testosterone levels of less than 10.5 nm/L (3 ng/mL) but greater than 7.0 nm/L (2 ng/mL) are hypogonadal, and whether these hypogonadal men would benefit from replacement, especially if their gonadotropin levels are normal. Even though older men have reduced muscle mass, decrease in body hair, and decrease in bone mass, there have been no conclusive data demonstrating that these findings are the result of age-associated reduction in testosterone levels. In fact, the argument can just as well be made that even if an elderly man has a testosterone level in what would be considered the normal range, his current level is below what it would have been when he was younger and, therefore, he is "hypogonadal." This concept is supported by the evidence of a steady decline in testosterone levels, which reportedly start to fall by the beginning at the fourth decade of life. Measurements of free or bioavailable testosterone should be considered experimental, until they are clearly shown to be a better marker of hypogonadism in the elderly than total testosterone levels. Therefore, measurement of free or bioavailable testosterone is not currently justified.

When a testosterone level is found to be below 7.0 nm/L (2 ng/mL), evaluation should proceed with measurement of gonadotropins, prolactin, etc., regardless of age. However, the issue that is not clear is what should be done for the healthy individual who does present with a testosterone level between 7.0 and 10.5 nm/L (2–3 ng/mL). Should these individuals have gonadotropin and prolactin levels measured? This decision should be made based on the primary purpose for which the testosterone measurement was initially made. If the testosterone level was obtained because of the clinical suspicion of hypogonadism and the value obtained was below the lower limits of normal for the reference laboratory, then gonadotropin levels should be determined. If the gonadotropin levels obtained are elevated, then appropriate evaluation and treatment for primary testicular failure should be performed. If the gonadotropin levels are low, evaluation for secondary hypogonadism should be considered, including measurement of prolactin and consideration of a pituitary imaging procedure. In these men with borderline low levels of testosterone, if prolactin and gonadotropin measurements do not provide an indication of the reason for the marginal testosterone levels, consideration can be given to some measurement of free or bioavailable testosterone. For the reasons discussed earlier in this section, a free testosterone level measured by a kit should be used cautiously. A more appropriate choice would be bioavailable testosterone measured by ammonium sulphate precipitation, free testosterone by a dialysis method, or separate measurements of SHBG and testosterone with calculation of free testosterone. If the free or bioavailable measurement is decreased and the man is clinically hypogonadal but the cause is not clear, consideration to testosterone replacement could be given, although the clinical response measurements have not yet been defined. Note that the reason for the testosterone measurement in these cases was a clinical suspicion of hypogonadism. Until the results of appropriate clinical studies (several NIH-sponsored studies addressing this issue are nearing completion) become available, measurement of testosterone in older men without a clinical suspicion of hypogonadism is inappropriate.

	Footnotes

 
The author wishes to thank Dr. Sanjay Asthana for review of the manuscript.

	References

Top Introduction References

 

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