Stable transfectants of human MCF-7 breast cancer cells with increased levels of the human folate receptor exhibit an increased sensitivity to antifolates.

A major problem in cancer therapy is tumor drug resistance such as is found with antifolates (e.g., methotrexate [MTX]). We are specifically interested in the role of the human folate receptor (hFR) in MTX resistance. To investigate whether transfection of hFR results in increased MTX uptake and increased drug sensitivity, human mammary carcinoma (MCF-7) cells and Chinese hamster ovary cells (CHO) (cells which do not express detectable levels of hFR) were transfected with hFR cDNA. Stable human mammary carcinoma and Chinese hamster ovary transfectants expressing high levels of hFR were selected for further analysis. Transfected cells which express increased levels of hFR grow more rapidly than mock transfected or wild type cells in media containing physiologic concentrations of folates. The hFR expressed by these cells is sorted to the plasma membrane and is functional as determined by cell surface binding of a radiolabeled folic acid derivative and by internalization of [3H]methotrexate. The stable transfectants that express increased levels of hFR are also more sensitive to MTX in physiologic concentrations of folates. We conclude that increased expression of hFR by human mammary carcinoma and Chinese hamster ovary cells cultured under these conditions results in an enhanced growth rate, increased folic acid binding, and increased MTX uptake and cytotoxicity.

Phase I study of intravenous Lu-labeled CC49 murine monoclonal antibody in patients with advanced adenocarcinoma.

CC49, a murine monoclonal antibody that recognizes the tumor-associated glycoprotein 72, was conjugated to the chemical chelate 1,4,7,10-tetraaza-1-(1-carboxy-3-(4-aminophenyl) propyl)-tris-4,7,10- ((carboxy)methyl)cyclododecane that had been labeled with a beta emitter, Lu. Preclinical studies had shown that Lu-labeled CC49 caused regression of human colon adenocarcinoma xenografts in nude mice. Patients with advanced adenocarcinoma who had failed standard treatment and whose tumors expressed the tumor-associated glycoprotein 72 antigen were eligible for treatment to determine the maximum tolerated dose of Lu-labeled CC49. The starting dose of Lu was 10 mCi/m2 given i.v. with the dose of CC49 held constant at 20 mg. Pharmacokinetic sampling and immunoscintigraphy were performed over the ensuing 3 weeks. The dose of radioactive Lu was escalated by 15 mCi/m2 for each successive dose level. Unexpected bone marrow toxicity developed in patients treated at the second dose level with 25 mCi/m2 Lu; two patients developed grade 4 thrombocytopenia, while the third patient developed grade 3 thrombocytopenia. Pharmacokinetic studies showed that the plasma half-life of the immunoconjugate was 67 h; whole-body retention, however, was prolonged with a biological half-life of 258 h. Serial gamma camera imaging localized known tumor in all patients, and also demonstrated prolonged Lu retention in the reticuloendothelial system (RES). Bone marrow dosimetry estimates ranged from 4 to 5 REMS/mCi Lu based on imaging and biopsy data. Analysis of bone marrow biopsies demonstrated that most of the Lu was localized in the cellular compartment and not in the bone. No antitumor responses were observed. Intravenous administration of 15 mCi/m2 Lu-labeled CC49 to previously treated advanced cancer patients was associated with acceptable hematological toxicity and was the maximum tolerated dose. However, prolonged retention of Lu in the RES, including the bone marrow, was observed and limited the dose of Lu that could be given. Additional studies are indicated to reduce RES uptake and retention of this immunoconjugate.

Why aged men become impotent.

Despite frequent erectile impotence in aged men, etiologic data are scarce. We evaluated 121 impotent male veterans (mean age, 68 +/- 5.3 years) to obtain information on potential pathophysiologic mechanisms. Subjects related a complete medical history and underwent physical examination, metabolic assessment, nocturnal penile tumescence monitoring, and vascular and neurologic assessment. The most frequent cause of impotence was the coexistence of neurologic and vascular disorders (30.3%). Other subjects had single causes, including vascular disease (21.1%), diabetic neuropathy (17.1%), nondiabetic neuropathy (10.5%), and psychopathology (9.2%). Remaining patients suffered from adverse drug effects (3.9%), hypogonadism (2.6%), and Peyronie's disease (1.3%). Five patients were objectively impotent on the basis of nocturnal penile tumescence, but otherwise normal. We conclude that geriatric impotence is primarily related to vascular or neurologic dysfunction. However, 15.7% of aged impotent men may have reversible impotence (eg, psychogenic causes or hypogonadism), and an additional 31.5% may have a treatable disorder (eg, penile neuropathy).

Mechanisms subserving the physiological nocturnal relative hypoprolactinemia of healthy older men: dual decline in prolactin secretory burst mass and basal release with preservation of pulse duration, frequency, and interpulse interval--a General Clinical Research Center study.

Increasing age is accompanied by decrements in randomly obtained, fasting, or frequently sampled serum PRL concentrations. The precise neuroendocrine mechanisms underlying such relative hypoprolactinemia in aging are incompletely understood. In the present study, we sampled blood at 2.5-min intervals overnight in 11 young (aged 21-34 yr) and 8 older (aged 62-72 yr) healthy men for subsequent chemiluminescence-based assay of serum PRL concentrations. The mean (+/- SEM) serum PRL concentration was significantly reduced at 4.3 +/- 0.78 microg/L in older men compared with 9.5 +/- 1.2 microg/L in young volunteers (P = 0.0049). PRL concentrations correlated with serum testosterone (r = 0.473; P = 0.041), dehydroepiandrosteroen sulfate (r = +0.455, P = 0.05), and insulin-like growth factor I (r = 0.494; P = 0.032) levels. Deconvolution analysis was used to evaluate combined pulsatile and basal modes of PRL secretion. In older men, discrete PRL secretory bursts were marked by a significantly (2.4-fold) attenuated mass of hormone secreted per burst (amount of PRL secreted per unit distribution volume), viz. 1.6 +/- 0.23 (older) vs. 3.9 +/- 0.57 microg/L (young; P < 0.01). In contrast, PRL secretory burst frequency, interpulse interval, and pulse duration were invariant of age. Concomitantly, basal PRL secretion was reduced by 2-fold in older subjects, namely to 0.00030 +/- 0.00027 (older) vs. 0.00065 +/- 0.0002 microg/L/min (young; P < 0.01). The amount of total PRL secretion that was pulsatile averaged 82 +/- 5.3% in young and 99 +/- 0.13% in older men (P = 0.012), indicating preferential loss of the basal mode of PRL release in aging. Assuming that basal PRL secretion mirrors functional pituitary lactotroph cell secretory mass, whereas pulsatile PRL release reflects effective (net) intermittent hypothalamic drive to responsive lactotroph cells, then our results suggest both an attrition in lactotroph cell mass and an impoverishment of net positive hypothalamic (agonistic) input to lactotrophs in older men. Given the multiple roles of PRL reported in experimental animals (e.g. on the one hand to support immune function and adrenal androgen biosynthesis and on the other hand to activate intraprostatic growth factors), we suggest that the nocturnal relative hypoprolactinemia observed in healthy aging men may have both adaptive and maladaptive clinical implications to target tissues.

Pulsatile iv infusion of recombinant human LH in leuprolide-suppressed men unmasks impoverished Leydig-cell secretory responsiveness to midphysiological LH drive in the aging male.

The present investigation tests the clinical hypothesis that Leydig-cell responsiveness to pulsatile and midphysiological LH drive is impaired in older men. To this end, we implemented a novel clinical investigative paradigm consisting of preadministration of an LH-down-regulating dose (3.75 mg) of leuprolide acetate followed, 3-4 wk later, by controlled challenge of the testis, with pulsatile iv infusions of saline vs. recombinant human (rh) LH. Based on a preliminary dose-finding experiment, we evaluated LH action in 8 young (ages, 18-25 yr) and 7 older (ages, 60-85 yr) volunteers by infusing eight consecutive 6-min squarewave pulses of saline or 50 IU rhLH iv every 2 h. Analyses were carried out 48 or 72 h apart in a prospective, randomly assigned, double-blind, within-subject cross-over design. Serum concentrations of T (RIA) and LH (immunoradiometric assay) were measured in blood sampled every 10 min concurrently. Leuprolide injection suppressed pre-LH-infusion (0800 h baseline) serum T concentrations (pooled mean +/- SEM) markedly in both age groups (P < 10(-3)); namely, to 40 +/- 20 ng/dl (young) and 12 +/- 3.1 ng/dl (older; P < 0.05 vs. young) (to convert to nM, multiply by 0.0347). Successive iv pulses of rhLH stimulated T output, over time, to an asymptotic maximum of 166 +/- 42 ng/dl in young men (P = 0.0008 vs. saline) and 57 +/- 9.8 ng/dl in older subjects (P = NS vs. saline, and P < 0.05 vs. young). Further regression analyses identified significant reductions of both the initial rate and maximum of the time-dependent incremental rise in LH-driven serum T concentrations in older men. In contrast, infused serum LH concentrations, distribution volumes, and calculated LH half-lives were comparable in the two age cohorts. We conclude that older men manifest both a delayed initial and reduced maximal serum T concentration rise compared with young men exposed to identical controlled midphysiological pulsatile LH drive.

Muting of androgen negative feedback unveils impoverished gonadotropin-releasing hormone/luteinizing hormone secretory reactivity in healthy older men.

Plasma bioavailable testosterone concentrations decline in healthy older men without a uniformly commensurate rise in serum LH concentrations, which disparity is consistent with a hypothesis of relative hypogonadotropism. Likewise, preserved gonadotrope responsiveness to exogenous GnRH stimulation, despite an attenuated amplitude of endogenous LH pulses, points to reduced hypothalamic GnRH feedforward signaling in aging males. To appraise GnRH/LH secretory reserve more directly in older men, we have compared daily LH secretion, driven by profound short-term blockade of androgen biosynthesis by oral ketoconazole administration, in nine young (ages, 18-32 yr) and seven older (ages, 60-73 yr) volunteers. The ability to unleash endogenous GnRH-driven LH secretion in response to acute testosterone withdrawal was quantitated by sampling blood every 10 min, for 24 h, followed by high-precision immunoradiometric assay. The resultant serum LH concentration profiles were analyzed by: 1) model-free discrete peak detection (Cluster) analysis; 2) the approximate entropy statistic to quantitate pattern regularity; and 3) 24-h rhythmic (cosinor) analysis. At baseline, mean and integrated (24-h) serum LH concentrations were similar in both age cohorts. However, Cluster analysis established an elevated LH peak frequency [18 +/- 0.86 (older) vs. 13 +/- 1.3 pulses/24 h (young), P = 0.0028] and a reduced incremental LH pulse area [37 +/- 6.9 (older) vs. 106 +/- 20 (young) IU/L x min, P = 0.016] in older men. Approximate entropy calculations also revealed more irregular LH release patterns in older men before intervention (P = 0.00089). Feedback stress, achieved by ketoconazole-induced androgen deprivation, unmasked further neuroregulatory defects in older volunteers, who failed to equivalently increase the: 1) mean (24-h) serum LH concentration [i.e. to 5.0 +/- 0.99 (older men) vs. 9.0 +/- 1.1 (young) IU/L, P = 0.000071]; 2) maximal LH peak height (to 6.1 +/- 1.1 vs. 10.4 +/- 1.2 IU/L, P = 0.00043); 3) incremental LH pulse area (to 41 +/- 8.8 vs. 87 +/- 20 IU/L x min, P = 0.016); 4) interpeak nadir serum LH concentration (to 4.0 +/- 0.77 vs. 7.9 +/- 1.0 IU/L, P < 10(-6)); 5) the quantitable irregularity of LH release (P = 0.00089); and 6) the mesor of 24-h rhythmic LH secretion (P = 0.000062). In summary, experimental imposition of a novel hypoandrogenemic open-loop feedback stressor, for 48 h, to heighten hypothalamic GnRH feedforward drive, unveils impoverished augmentation of LH pulse mass, impaired orderliness of LH release, and diminished 24-h rhythmic LH secretion in older men. The foregoing trilogy of neuroregulatory defects identifies unequivocally attenuated hypothalamo-pituitary reactivity to muting of androgen negative feedback in the aging male.

Amplified nocturnal luteinizing hormone (LH) secretory burst frequency with selective attenuation of pulsatile (but not basal) testosterone secretion in healthy aged men: possible Leydig cell desensitization to endogenous LH signaling--a clinical research center study.

The specific mechanisms underlying the relative hypogonadism of aging remain to be elucidated fully. We used frequent venous sampling (every 2.5 min), sensitive and specific LH and testosterone assays, and deconvolution analysis of the endocrine time series to delineate the differences between healthy young (n = 10, age 21-34 yr) and aged (n = 8, age 62-74 yr) men in the nocturnal secretion of LH and testosterone and their half-lives. We found that elderly men vs. young men had more frequent bursts of LH secretion (1.4 vs. 0.9/h, P = 0.003), less testosterone secreted per testosterone secretory burst (9.2 vs. 17.0 nmol/L, P = 0.021), and less testosterone secreted per hour (10.7 vs. 25.0 nmol/L.h, P = 0.05). As the frequency of nocturnal LH secretory bursts increased, the frequency of testosterone bursts decreased (r = -0.746, P = 0.034). We conclude that healthy aging is associated with diminished nocturnal testosterone production attributable to 1) a decrement in the mass of testosterone released per burst and 2) an inadequate response by the pituitary gland to enhance testosterone production via an accelerated LH secretory pulse frequency. We speculate that this may reflect a partial desensitization of Leydig cells to LH.

Older men manifest multifold synchrony disruption of reproductive neurohormone outflow.

Under a working clinical hypothesis that aging putatively disrupts neuroendocrine control mechanisms, here we test a specific corollary notion that transitions in sleep stage, oscillations in nocturnal penile tumescence (NPT; a neurogenically organized signal), and the rates of instantaneous secretion of LH and/or testosterone are jointly synchronous in healthy young, but not older, men. To this end, we evaluated 10 young (aged 21-31 yr) and 8 older (aged 65-74 yr) men by intensive overnight multisite monitoring, viz. simultaneous electro-encephalogram and NPT recordings (every 30 s) and remote blood sampling (every 2.5 min) to quantitate LH and testosterone release. Waveform-independent deconvolution and cross-correlation analyses of these neurohormone outflow measures revealed that healthy young men sustain four salient physiological linkages overnight: 1) a strong inverse (confirmatory) relationship between sleep stage and NPT activity, such that deeper sleep is accompanied by suppression of NPT; 2) consistent coupling between NPT and testosterone secretion, wherein heightened NPT activity respectively precedes and follows increased testosterone secretion by 12.5-32.5 and 50-60 min; 3) evident synchrony between sleep stage and testosterone secretion, in which testosterone secretion increases over a 30-min window (-2.5 to 25 min) while sleep deepens; and 4) a close temporal linkage between instantaneous LH release and NPT oscillations, whereby LH secretion increases 55-62.5 min before and again 5-30 min after NPT declines. In contrast, older men manifested global loss of expected young adult synchrony; namely, 1) abolition of the inverse relationship between sleep stage and NPT, 2) decorrelation of NPT oscillations and testosterone secretion, 3) decoupling of testosterone release and deep sleep, and 4) abrogation of the linkage between LH secretion and penile detumescence. In summary, high intensity overnight monitoring of multiple reproductive neuroendocrine outflow measures simultaneously in young men delineates prominent neurophysiological coupling among sleep transitions and NPT activity, LH and testosterone secretion or NPT oscillations, and testosterone secretion and deepening sleep stage. In contrast, healthy older men exhibit near-universal disruption of physiological young adult synchronicity. Thus, we conclude that male reproductive aging is marked by erosion of coordinate regulation among sleep transitions, central nervous system-directed NPT activity, and hypothalamically driven episodic GnRH/LH (and thereby Leydig cell testosterone) secretion. Whether analogous multifold uncoupling of neurohormone signals emerges in the course of reproductive aging in women or in nonhuman species is not yet known.

Impact of age on cortisol secretory dynamics basally and as driven by nutrient-withdrawal stress.

The present study tests the clinical hypothesis that aging impairs homeostatic adaptations of cortisol secretion to stress. To this end, we implemented a short-term 3.5-day fast as an ethically acceptable metabolic stressor in eight young (ages 18-35 yr) and eight older (ages 60-72 yr) healthy men. Volunteers were studied in randomly ordered fed vs. fasting sessions. To capture the more complex dynamics of cortisol's feedback control, blood was sampled every 10 min for 24 h for later RIA of serum cortisol concentrations and quantitation of the pulsatile, entropic, and 24-h rhythmic modes of cortisol release using deconvolution analysis, the approximate entropy statistic, and cosine regression, respectively. The stress of fasting elevated the mean (24-h) serum cortisol concentration equivalently in the two age cohorts [i.e. from 7.2 +/- 0.35 to 11.6 +/- 0.71 microg/dL in young men and from 7.7 +/- 0.39 to 12.6 +/- 0.59 microg/dL in older individuals (P < 10(-7))]. The rise in integrated cortisol output was driven mechanistically by selective augmentation of cortisol secretory burst mass (P = 0.002). The resultant daily (pulsatile) cortisol secretion rate increased significantly but equally in young (from 94 +/- 6.3 to 151 +/- 15 microg/dL x day) and older (from 85 +/- 5.4 to 145 +/- 7.3 microg/dL x day) volunteers (P < 10(-4)). Nutrient restriction also prompted a marked reduction in the quantifiable regularity of (univariate) cortisol release patterns in both cohorts (P < 10(-4)). However, older men showed loss of joint synchrony of cortisol and LH secretion even in the fed state, which failed to change with metabolic stress (P < 10(-6)). In addition, older individuals maintained a premature (early-day) cortisol elevation in the fed state and unexpectedly evolved an anomalous further cortisol phase advance of 99 +/- 16 min during fasting (P < 10(-5)). Caloric deprivation in aging men also disproportionately elevated the mesor of 24-h rhythmic cortisol release (P = 10(-7)) and elicited a greater increment in the mean day-night variation in cortisol secretory-burst mass (P < 0.01 vs. young controls). Lastly, short-term caloric depletion in older subjects paradoxically normalized their age-associated suppression of the 24-h rhythm in cortisol interburst intervals. In summary, acute metabolic stress in healthy aging men (compared with young individuals) unmasks distinct, albeit complex, disruption of cortisol homeostasis. These dynamic anomalies impact the feedback-dependent and time-sensitive coupling of pulsatile and 24-h rhythmic cortisol secretion. Nutrient-withdrawal stress in the older male heightens the cortisol phase disparity already evident in fed elderly individuals. Conversely, the stress of fasting in young men paradoxically reproduces selected features of the aging unstressed (fed) cortisol axis; viz., abrogation of joint cortisol-LH synchrony and suppression of the normal diurnal variation in cortisol burst frequency. Whether fasting would unveil analogous disruption of feedback-dependent control of the corticotropic axis in healthy aging women is not yet known.

Disruption of the young-adult synchrony between luteinizing hormone release and oscillations in follicle-stimulating hormone, prolactin, and nocturnal penile tumescence (NPT) in healthy older men.

The healthy human male hypothalamo-pituitary-gonadal axis exhibits age-dependent loss of coordinate LH-testosterone secretion. A putative independent defect in Leydig-cell steroidogenesis with aging would confound the attribution of such LH-testosterone asynchrony to a hypothalamo-pituitary locus per se. Accordingly, here we appraise by sampling every 2.5 min overnight the joint synchrony of moment-to-moment LH release with simultaneously monitored pituitary FSH secretion, prolactin release, and nocturnal penile tumescence (NPT) oscillations, as a neurophysiological correlate of sleep regulation) in 10 young (ages 21-34) and 8 older (ages 62-72) healthy men. Joint synchrony for paired LH-FSH, LH-prolactin, and LH-NPT observations in young vs. older individuals was quantified by the cross-approximate entropy (cross-ApEn) statistic, with larger cross-ApEn values indicating greater two-variable asynchrony. Concomitantly, we assessed (possible) univariate changes with age for each of LH, FSH, prolactin, and NPT, as quantified by approximate entropy (ApEn). Hormone assays were performed by random-access direct chemiluminescence analyzer. Overnight mean (+/- SEM) serum LH concentrations (IU/L) were equivalent in older (3.1 +/- 0.31 IU/L) and younger (2.9 +/- 0.29) men, as were their serum total testosterone concentrations; viz., 425 +/- 48 (older) and 523 +/- 40 (younger) ng/dL. However, all three sets of paired time-series were significantly more asynchronous in the older cohort. First, cross-ApEn of paired LH-FSH release was significantly higher (or more asynchronous) in older subjects; viz., 1.902 +/- 0.022 in older men vs. 1.607 +/- 0.058 in younger individuals (P = 0.0005). Second, cross-ApEn of paired LH and prolactin release was 1.744 +/- 0.085 in older volunteers vs. 1.346 +/- 0.084 in younger subjects (P = 0.0046). Third, and most notably, cross-ApEn for the joint LH-NPT observation time-series was significantly greater in older subjects at 1.771 +/- 0.056 vs. 1.223 +/- 0.086 (young) (P = 0.0001), thereby denoting loss of coordination between (neural) signals directing intermittent LH secretion and those governing sleep-associated penile tumescence in older men. Among one-variable results, only ApEn of LH release was significantly higher in older individuals at 1.323 +/- 0.058 vs. 0.897 +/- 0.089 in younger subjects (P = 0.0019), signifying greater disorderliness of the LH secretory process in aged men. Individual ApEn values of FSH and prolactin release and NPT were age-invariant. In ensemble, the present clinical experiments indicate that, within the aging male reproductive axis, bihormonal network disruption is more pronounced than individual signal disruption. We suggest that abrogation of joint synchrony among hypothalamically directed pituitary hormones and a neurogenically organized sexual response (nocturnal penile tumescence) can be unified thematically under an hypothesis of disrupted central nervous system hypothalamo-pituitary network coordination in human aging. Such implicit disarray of multinodal communication is of consequence both scientifically and clinically, especially in proposing aging theories and intervention strategies.

Joint basal and pulsatile hypersecretory mechanisms drive the monotropic follicle-stimulating hormone (FSH) elevation in healthy older men: concurrent preservation of the orderliness of the FSH release process: a general clinical research center study.

To appraise the neuroendocrine mechanisms that underlie a selective (monotropic) elevation of serum FSH concentrations in healthy older men, we sampled blood in 11 young (ages 21-34) and 8 older men (ages 62-72) men every 2.5 min overnight. Serum FSH concentrations were quantitated in an automated, high-sensitivity, chemiluminescence-based assay. Rates of basal and pulsatile FSH secretion were estimated by deconvolution analysis, and the orderliness of the FSH release process via quantitated the approximate entropy statistic. Statistical analysis revealed that healthy older men manifest dual neuroendocrine hypersecretory mechanisims; specifically, a 2-fold increase in the basal (nonpulsatile) FSH secretion rate, and a concurrent 50% amplification of FSH secretory burst mass (and amplitude). The regularity or orderliness of ad seriatim FSH release is preserved in older individuals. We postulate that higher basal FSH secretion in older men is a consequence of reduced testosterone negative feedback, whereas amplified FSH secretory burst mass reflects net enhanced stimulation of gonadotrope cells by endogenous FSH secretagogues (e.g. GnRH and/or activin). The foregoing specific mechanisms driving heightened FSH secretion in older men contrast with the lower-amplitude pulsatility and more disorderly patterns of LH release in the same individuals. Thus, the present data illuminate an age-dependent disparity in the disruption of FSH neuroregulation in the aging male.

Fasting suppresses pulsatile luteinizing hormone (LH) secretion and enhances orderliness of LH release in young but not older men.

Pulsatile gonadotropin secretion and sex-steroid concentrations are suppressed reversibly in young fasted or malnourished human subjects. In this study, we investigated the impact of age on the dynamic neuroendocrine mechanisms underlying this stress response in healthy young (age, 28 +/- 3 yr, n = 8) vs. older (age 67 +/- 2 yr, n = 8) men with similar body mass indices (mean, 26 +/- 0.6 vs. 26 +/- 1.3 kg/m2, respectively). Serum LH concentrations were measured by immunoradiometric assay (IRMA) in blood collected at 10-min intervals over 27 h on a control (fed) day and on the third day of a 3.5-day fast (water only) assigned in randomized order. After 24 h of basal sampling, GnRH (10 micrograms i.v. bolus) was administered to test gonadotrope responsiveness. Cortisol, dehydroepiandrosterone sulfate, androstenedione, testosterone, FSH, GH, and PRL were measured in 24-h pooled serum as positive and negative control hormones. Approximate entropy was used to quantitate the orderliness of LH release over 24 h, and a multiple-parameter deconvolution method was applied to quantify pulsatile LH secretion and LH half-life. In the fed state, older men exhibited elevated mean (24-h pooled) serum FSH and cortisol concentrations compared with young controls but equivalent serum LH concentrations and reduced serum GH, free testosterone, androstenedione, and dehydroepiandrosterone sulfate concentrations. Fed older men also manifested a lower frequency and amplitude of 24-h pulsatile LH secretion, and, by approximate entropy calculations, a more disorderly pattern of basal LH release than younger individuals. Three- and one-half days of fasting evoked 40% and 47% increases in mean (24-h) serum cortisol concentrations in young and older men, respectively (P < 0.01 vs. fed, but P = not significant for percentage rise in older vs. young men). Concurrently, fasting induced a 2.1-fold fall in the 24-h endogenous LH production rate in young men (fed 36 +/- 9.7 vs. fasted 17 +/- 2.0 IU/L of distribution volume/day, P < 0.01), but did not significantly affect the daily LH secretion rate in older men (fed 27 +/- 4.5 vs. fasted 21 +/- 3.4 IU/day). The reduced LH production rate in fasting young men was accounted for by a 1.7-fold decline in the mass of LH secreted per burst (fed 2.5 +/- 0.45 vs. fasted 1.5 +/- 0.16 IU/L, P < 0.05), whereas LH burst mass in older men remained unchanged (and low) during fasting. In addition, in young men, during the 3.5-day fast the number of computer-resolved LH secretory bursts per 24 h decreased (fed 15 +/- 0.7 vs. fasted 11 +/- 0.7, P < 0.01), and the interburst interval increased (fed 94 +/- 4.2 vs. fasted 125 +/- 8.7 min, P < 0.05). In contrast, in older men in the fed state, basal LH peak frequency and serum free testosterone concentrations were reduced compared with corresponding values in young men, and did not decline further with fasting. Whereas the orderliness of LH release patterns increased significantly during fasting in the young men, the approximate entropy measure failed to change significantly in unfed older subjects. By cosinor analysis, young men showed lower 24-h mesor (mean of nyctohemeral rhythm of) serum LH concentrations than older volunteers during fasting. Moreover, young but not older men manifested preserved 24-h variations in LH interpulse intervals when fasting. Exogenously stimulated LH release (mean 3-h serum LH concentration or calculated mass of LH secreted) following a single i.v. injection of 10 micrograms GnRH was independent of age and fasting status. We conclude that the metabolic stressor of short-term fasting unmasks specific age-related neuroendocrine contrasts in the stress-responsive control of both the pulsatile and nyctohemeral regulation of the male hypothalamo-pituitary-gonadal-axis.

Unequal impact of short-term testosterone repletion on the somatotropic axis of young and older men.

The present clinical study compares the impact of low- and high-dose parenteral testosterone (T) supplementation on daily GH secretory patterns and serum IGF-I, IGFBP-1, and IGFBP-3 concentrations in healthy older (60-82 yr) and young (20-40 yr) men. To this end, we administered three consecutive weekly injections of randomly ordered saline and either a low (100 mg) or a high (200 mg) dose of testosterone enanthate im; namely, saline (n = 17, young and n = 16, older), a low dose (n = 8 young, n = 8 older) and a high dose (n = 9 young, and n = 8 older) of androgen. To monitor somatotropic-axis responses, blood was sampled every 10 min for 24 h for later chemiluminescence-based assay of serum GH, RIA of serum IGF-I, and immunoradiometric assay of serum IGFBP-1 and IGFBP-3 concentrations. Data were analyzed via a nested analysis of covariance statistical design. At baseline (saline injection), older, compared with young, men maintained: 1) similar serum total T, IGFBP-1, and IGFBP-3 but reduced IGF-I concentrations, namely, mean (+/- SEM) IGF-I 160 plus or minus 15 vs. 280 plus or minus 18 microg/liter, (P < 0.001); 2) reduced GH secretory burst mass (0.68 +/- 0.09 vs. 1.2 +/- 0.20 microg/liter, P = 0.031); 3) more disorderly GH release patterns (approximate entropy 0.501 +/- 0.058 vs. 0.288 +/- 0.021, P < 0.001); and 4) blunted 24-h rhythmic GH output (nyctohemeral amplitude 0.25 +/- 0.05 vs. 0.47 +/- 0.08 microg/liter, P = 0.025). Serum T concentrations (ng/dl) did not differ in the two age groups supplemented with either a low dose [550 +/- 50 (young) and 544 +/- 128 (older)] and high [1320 +/- 92 (young) and 1570 +/- 140 (older)] dose of T. The 100-mg dose of androgen exerted no detectable effect on GH secretion in either age cohort but increased the serum IGF-I concentration in young men by 20% (P = 0.00098). The 200-mg dose of T failed to alter daily GH production in young volunteers but in older men stimulated: 1) a 2.03-fold rise in the mean (24-h) serum GH concentration (P = 0.0053, compared with the response to saline); 2) a 1.20-fold increase in basal (nonpulsatile) GH production (P = 0.039); 3) a 2.15-fold amplification of GH secretory burst mass (P = 0.0020); 4) a 2.17-fold elevation of the Mesor of nyctohemeral GH output (P = 0.025); 5) a 1.79-fold enhancement in GH approximate entropy (P = 0.0003); and 6) a 40% increase in the fasting serum IGF-I concentration (P = 0.000005). Multivariate statistical analysis indicated that following high-dose T administration, the E2 increment significantly predicted the IGF-I increment in both age groups combined (P = 0.003); T dose positively forecast the serum total IGF-I concentration (P = 0.0031); and age and T dose jointly determined serum LH concentrations (P = 0.031). In summary, neither a physiological nor a pharmacological dose of T administered parenterally for 3 wk augments daily GH secretion in eugonadal young men. In contrast, a high dose of aromatizable androgen significantly amplifies 24-h basal, pulsatile, entropic, and nyctohemerally rhythmic GH production and elevates the serum IGF-I concentration in older men. The mechanistic basis for the foregoing age-related distinction in GH/IGF-I axis responsivity to T is not known.

Differential impact of age, sex steroid hormones, and obesity on basal versus pulsatile growth hormone secretion in men as assessed in an ultrasensitive chemiluminescence assay.

A chemiluminescence-based GH assay with 30- to 100-fold increased sensitivity recently disclosed combined basal and pulsatile GH secretion in men. However, how age, sex steroid hormones, and obesity singly and jointly influence the basal vs. pulsatile modes of GH release is not known. We used the foregoing assay (detection threshold, 0.002-0.005 microgram/L) and high sensitivity and specificity (> or = 90% each) deconvolution analysis to quantitate basal and pulsatile GH secretion from 24-h serum GH concentration profiles in 26 healthy lean and obese men, whose ages spanned 18-63 yr and whose percentage body fat ranged from 12-47%. Concentrations of serum insulin-like growth factor I (IGF-I), IGF-I-binding protein-1 (IGFBP-1), and IGFBP-3 were related to specific measures of basal or pulsatile GH release. We observed that mean (24-h) serum GH concentrations embraced a 140-fold range from 0.013-1.8 micrograms/L and were related negatively to age (r = -0.50; P < 0.01), percentage body fat (r = -0.620; P < 0.01), and their interaction (r = -0.610; P < 0.01). In contrast, testosterone was a robustly positive statistical determinant of mean serum GH values (r = 0.628; P = 0.0006). Stepwise multivariate regression analysis disclosed that percentage body fat alone and jointly with the serum testosterone concentration controlled, respectively, 38% and 50% of the total variability in GH levels (P = 0.0013 and P = 0.0008). As assessed by deconvolution analysis, GH secretory burst mass was negatively related to percentage body fat (r = -0.621; P < 0.01) and positively to serum testosterone (r = 0.529; P = 0.0054). The calculated half-life of GH correlated positively with serum estradiol (r = 0.447; P = 0.032), and negatively with percentage body fat (r = -0.437; P = 0.048). Basal GH secretion rates were negatively related to serum estradiol (r = -0.485; P = 0.016). In contrast, GH secretory burst frequency and duration were unrelated to age, percentage body fat, or sex steroids. The fraction of total GH secreted in bursts was negatively correlated with the body mass index (r = -0.540; P < 0.01). Serum IGF-I concentrations were positively related to total pulsatile GH secretion (r = 0.690; P = 0.0011) and negatively to age (r = -0.597; P = 0.007) and percentage body fat (r = -0.611; P = 0.009).(ABSTRACT TRUNCATED AT 400 WORDS)

Penile blood flow by xenon-133 washout.

Penile erectile failure is often attributed to abnormalities of vascular supply or drainage, but few direct measurements of penile blood flow have been made. We describe the xenon washout method for measurement of penile blood flow, and present the results obtained in a group of normal and impotent subjects. The procedure was performed with standard nuclear imaging equipment. Flaccid-state penile blood flow in the impotent patients studied was not significantly different from the normal group, suggesting that flaccid-state measurements may not be helpful in evaluation of erectile failure. However, this method can be used to measure penile venous outflow with stimulated or induced erection, and may provide a method for detecting abnormal venous leakage.

Derivatization of 5-fluorouracil with 4-bromomethyl-7-methoxycoumarin for determination by liquid chromatography-mass spectrometry.

A robust new analytical method has been developed for the determination of 5-fluorouracil (5-FU) in human plasma samples using high-performance liquid chromatography-tandem mass spectrometry (HPLC-MS/MS). The method is based on a liquid-liquid extraction procedure, precolumn derivatization, reversed-phase HPLC separation, and detection using atmospheric pressure chemical ionization and selected reaction monitoring. The derivatization agent used was 4-bromomethyl-7-methoxycoumarin. The internal standard for the assay procedure was a stable isotope labeled analog of 5-FU. The lower limit of quantitation was 1.0 ng/mL using 500 microL aliquots of plasma. Sample throughput on the mass spectrometer was approximately 17 samples/h (3.5 min/sample). The method was fully validated. The recovery of 5-FU averaged 76.1%. The accuracy of the assay, assessed from quality control samples, ranged from 99.1% to 104.3% (% theoretical). The overall interassay precision (% RSD) was 2.7%, and the intraassay precision (% RSD) ranged from 1.5% to 3.9%. The derivatized samples were found to be stable under sample analysis conditions and during refrigerator storage. The method was specific for the determination of 5-FU.

Mechanisms of conjoint failure of the somatotropic and gonadal axes in ageing men.

Endogenous growth hormone (GH) production falls by 50% every 7 years and bioavailable testosterone concentrations decline concomitantly by 12-15% every decade in ageing men. Despite this temporal parallelism, the neuroendocrine bases of the somatopause and gonadopause are not known. This knowledge deficit contrasts with the recent unfolding of new insights into the nature of oestrogen-dependent control of the GH-insulin-like growth factor (IGF)1 axis in pre- and postmenopausal women. The present overview examines the postulate that the pathophysiology of somatopause and gonadopause in ageing men is bidirectionally linked. According to this broader thesis, hyposomatotropism accentuates Leydig cell steroidogenic failure and, conversely, progressive androgen deficiency exacerbates the decline in GH-IGF1 output in ageing.

Two-week pulsatile gonadotropin releasing hormone infusion unmasks dual (hypothalamic and Leydig cell) defects in the healthy aging male gonadotropic axis.

OBJECTIVE: To examine the possibility that lower serum bioavailable testosterone concentrations, without increased LH release, in healthy older men, reflects hypothalamic GnRH deficiency. DESIGN: We used a randomized, double-blind, placebo-controlled design. METHODS: We treated each of five young (ages 20-34 years) and five older (ages 60-78 years) men with 2 weeks of randomized infusions of saline or pulsatile GnRH (100 ng/kg i.v. every 90 min). RESULTS: At baseline (saline infusion), older men had more LH pulses (young compared with old, 10 +/- 0.6 compared with 15 +/- 1, P = 0.0026) per 24h, reduced fractional LH pulse amplitude (219 +/- 17% compared with 167 +/- 40%, P = 0.0376), and more disorderly hormone release as judged by approximate entropy (ApEn) (LH, P < or = 0.0001; testosterone, P < or = 0.0047). In response to pulsatile i.v. GnRH infusions, serum 24-h LH concentrations (measured by immunoradiometric assay (IRMA)), increased equivalently in young and older men (to 7.3 +/- 1.2 and 7.2 +/- 1.8 IU/l respectively). GnRH treatment also normalized LH pulse frequency and amplitude, ApEn, and plasma biologically active LH (pooled) concentrations. In contrast, 24-h testosterone concentrations failed to increase equivalently in older men (young compared with old, 869 +/- 88 compared with 517 +/- 38 ng/dl, P = 0.0061), reflecting lower testosterone peak maxima (995 +/- 108 compared with 583 +/- 48 ng/dl, P = 0.0083) and interpeak nadirs (750 +/- 87 compared with 427 +/- 26 ng/dl, P = 0.0073). CONCLUSIONS: We have demonstrated that, in older men, successful reconstitution of 24-h pituitary (bioactive) LH output and pulsatile (IRMA) LH release patterns could be achieved by a fixed exogenous GnRH pulse signal, thereby implicating altered endogenous hypothalamic GnRH release in the relative hypogonadotropism of aging. The failure of testosterone concentrations to increase concomitantly points to a simultaneous Leydig cell defect. We conclude that aging in men is marked by a dual defect in the central nervous system-pituitary-Leydig cell axis.

Sexual function after heart transplantation.

To define sexual interest, ability, and activity before and after heart transplantation, we surveyed all discharged, male heart transplant recipients from our institution. Of the 115 potential subjects, 71 (62%) responded. Respondents were predominantly (89%) white, had a mean age of 47.9 years (24 to 64 years), and most (74%) were living with their spouses. Pretransplant libido was strong and remained unchanged after heart transplantation. Transplant recipients reported their partner's libido to be strong, and even stronger after transplantation than before (p = 0.033). In contrast, erectile rigidity and orgasmic ability were impaired before, and declined further after, the transplant procedure. Respondents perceived this gap between libido and sexual ability to be a problem, and interest in evaluation and treatment was high.

Erectile failure in the aged: evaluation and treatment.

With aging, there are changes in both libido and erectile function. Although the majority of aged men remain interested in sex, less than 15% report continued sexual intercourse. The cause of this "libido-potency gap" is due primarily to erectile failure. Penile erection is dependent upon a complex interaction of the autonomic nervous system, cardiovascular system, and local neurotransmitters such as acetylcholine and vasoactive intestinal polypeptide. Sexual stimulation causes augmented blood flow into the corpora cavernosa, and restricted outflow, resulting in penile rigidity. With aging, there is a decline in gonadal steroids, nerve conduction velocity, and vascular compliance, any of which could interfere with normal erections. When disease is superimposed on the normal changes of aging, erectile function is further impaired. Evaluation of an elderly male with impotence may consist of a detailed drug history and trial of alternate therapy, as in the case of adverse drug reactions. More often, evaluation entails hormonal assays, penile vascular assessment, neurologic assessment, and an evaluation of nocturnal erectile function. Based on the results of these assessments, appropriate treatment alternatives can be chosen. With the availability of multiple treatment options, patients and physicians can now choose from a range of noninvasive or invasive alternatives depending upon the etiology, associated disorders, and preference of the patient.