Modelling Hydrocortisone Pharmacokinetics on a Subcutaneous Pulsatile Infusion Replacement Strategy in Patients with Adrenocortical Insufficiency

In the context of glucocorticoid (GC) therapeutics, recent studies have utilised a subcutaneous hydrocortisone (HC) infusion pump programmed to deliver multiple HC pulses throughout the day, with the purpose of restoring normal circadian and ultradian GC rhythmicity. A key challenge for the advancement of novel HC replacement therapies is the calibration of infusion pumps against cortisol levels measured in blood. However, repeated blood sampling sessions are enormously labour-intensive for both examiners and examinees. These sessions also have a cost, are time consuming and are occasionally unfeasible. To address this, we developed a pharmacokinetic model approximating the values of plasma cortisol levels at any point of the day from a limited number of plasma cortisol measurements. The model was validated using the plasma cortisol profiles of 9 subjects with disrupted endogenous GC synthetic capacity. The model accurately predicted plasma cortisol levels (mean absolute percentage error of 14%) when only four plasma cortisol measurements were provided. Although our model did not predict GC dynamics when HC was administered in a way other than subcutaneously or in individuals whose endogenous capacity to produce GCs is intact, it was found to successfully be used to support clinical trials (or practice) involving subcutaneous HC delivery in patients with reduced endogenous capacity to synthesize GCs.

Effect of pulsatile growth hormone administration to the growth-restricted fetal sheep on somatotrophic axis gene expression in fetal and placental tissues

We have previously reported (Bauer MK, Breier BH, Bloomfield FH, Jensen EC, Gluckman PD, and Harding JE. J Endocrinol 177: 83–92, 2003) that a chronic pulsatile infusion of growth hormone (GH) to intrauterine growth-restricted (IUGR) ovine fetuses increased fetal circulating IGF-I levels without increasing fetal growth. We hypothesized a cortisol-induced upregulation of fetal hepatic GH receptor (GH-R) mRNA levels, secondary increases in IGF-I mRNA levels, and circulating IGF-I levels, but a downregulation of the type I IGF receptor (IGF-IR) as an explanation. We, therefore, measured mRNA levels of genes of the somatotrophic axis by real-time RT-PCR in fetal and placental tissues of fetuses with IUGR (induced by uteroplacental embolization from 110- to 116-days gestation) that received either a pulsatile infusion of GH (total dose 3.5 mg/day) or vehicle from 117–126 days and in control fetuses ( n = 5 per group). Tissues were collected at 127 days (term, 145 days). Fetal cortisol concentrations were significantly increased in IUGR fetuses. However, in liver, GH-R, but not IGF-I or IGF-IR, mRNA levels were decreased in both IUGR groups. In contrast, in placenta, GH-R, IGF-I, and IGF-IR expression were increased in IUGR vehicle-infused fetuses. GH infusion further increased placental GH-R and IGF-IR, but abolished the increase in IGF-I mRNA levels. GH infusion reduced IGF-I expression in muscle and increased GH-R but decreased IGF-IR expression in kidney. IUGR increased hepatic IGF-binding protein (IGFBP)-1 and placental IGFBP-2 and -3 mRNA levels with no further effect of GH infusion. In conclusion, the modest increases in circulating cortisol concentrations in IUGR fetuses did not increase hepatic GH-R mRNA expression and, therefore, do not explain the increased circulating IGF-I levels that we found with GH infusion, which are likely due to reduced clearance rather than increased production. We demonstrate tissue-specific regulation of the somatotrophic axis in IUGR fetuses and a discontinuity between GH-R and IGF-I gene expression in GH-infused fetuses that is not explained by alterations in phosphorylated STAT5b.

Age diminishes the testicular steroidogenic response to repeated intravenous pulses of recombinant human LH during acute GnRH-receptor blockade in healthy men

Testosterone (Te) concentrations fall gradually in healthy aging men. Postulated mechanisms include relative failure of gonadotropin-releasing hormone (GnRH), luteinizing hormone (LH), and/or gonadal Te secretion. Available methods to test Leydig cell Te production include pharmacological stimulation with human chorionic gonadotropin (hCG). We reasoned that physiological lutropic signaling could be mimicked by pulsatile infusion of recombinant human (rh) LH during acute suppression of LH secretion. To this end, we studied eight young (ages 19–30 yr) and seven older (ages 61–73 yr) men in an experimental paradigm comprising 1) inhibition of overnight LH secretion with a potent selective GnRH-receptor antagonist (ganirelix, 2 mg sc), 2) intravenous infusion of consecutive pulses of rh LH (50 IU every 2 h), and 3) chemiluminometric assay of LH and Te concentrations sampled every 10 min for 26 h. Statistical analyses revealed that 1) ganirelix suppressed LH and Te equally (> 75% median inhibition) in young and older men, 2) infused LH pulse profiles did not differ by age, and 3) successive intravenous pulses of rh LH increased concentrations of free Te (ng/dl) to 4.6 ± 0.38 (young) and 2.1 ± 0.14 (older; P < 0.001) and bioavailable Te (ng/dl) to 337 ± 20 (young) and 209 ± 16 (older; P = 0.002). Thus controlled pulsatile rh LH drive that emulates physiological LH pulses unmasks significant impairment of short-term Leydig cell steroidogenesis in aging men. Whether more prolonged pulsatile LH stimulation would normalize this inferred defect is unknown.

In the Adult Male Rhesus Monkey (Macaca mulatta), Unilateral Orchidectomy in the Face of Unchanging Gonadotropin Stimulation Results in Partial Compensation of Testosterone Secretion by the Remaining Testis

This study examined, in adult monkeys, the role that gonadotropin-independent mechanisms play in compensation of testosterone (T) secretion by the testis that remains after unilateral orchidectomy (UO). We employed a model (testicular clamp), in which endogenous gonadotropin secretion was abolished with a GnRH receptor antagonist, and the gonadotropin drive to the testes was concomitantly replaced with an invariant iv pulsatile infusion of recombinant human LH and FSH (1-min pulse every 2.5 h: LH, 0.08–0.12 IU/kg·pulse; FSH, 0.12–0.32 IU/kg·pulse) that provided the Leydig cells with a physiological stimulus. Within 5 h of UO (n = 5), circulating T concentrations had declined to 43% of pre-UO levels. By d 4, however, loss of the first testis was partially compensated, as reflected by the finding that circulating T had reached a plateau of 67% of the pre-UO level, where it remained for the duration of the study (39 d). That the recovery in circulating T was the result of increased T secretion by the remaining testis was suggested by the finding that the pulsatile pattern and decay of T during the intergonadotropin pulse interval before and after UO were indistinguishable. Interestingly, inhibin B production by the remaining testis also showed a delayed, albeit, minor, compensation (13% on d 10–11; P &gt; 0.05) after loss of the first testis. These results suggest that compensation in T production by the remaining testis after UO in adult monkeys may be achieved in part by a gonadotropin-independent mechanism that probably involves direct neural inputs to the primate testis.

Pulsatility does not alter the response to a physiological increment in glucagon in the conscious dog

The present study was designed to investigate if pulsatile hyperglucagonemia of physiological magnitude has greater efficacy in stimulating hepatic glucose production than constant glucagon. Paired studies were performed in conscious dogs. After insulin and glucagon were clamped at basal concentrations for 2 h, glucagon was elevated for 4 h with either a continuous infusion or pulses having physiological frequency and amplitude. With continuous infusion, plasma glucagon concentrations increased from 56 +/- 7 to 194 +/- 27 ng/l. With pulsatile infusion, glucagon concentrations started at 53 +/- 6 ng/l and then oscillated between 157 +/- 15 and 253 +/- 28 ng/l. Plasma insulin concentrations remained constant at basal levels. Glucose production was determined using a time-varying two-compartment model for glucose kinetics and deconvolution. After 15 min, glucose production had risen from 13.6 +/- 1.1 to 53.8 +/- 3.9 mumol.kg-1.min-1 with continuous infusion and from 12.9 +/- 0.6 to 50.6 +/- 2.9 mumol.kg-1.min-1 with pulsatile infusion. After 4 h, the production had fallen to 16.1 +/- 1.2 and 17.1 +/- 0.7 mumol.kg-1.min-1. In the present animal model with insulin held constant, no difference was noted between the response to continuous or pulsatile glucagon infusion.