An Assessment of Optimal Hydrocortisone Replacement Therapy

OBJECTIVE To assess the management of hydrocortisone replacement therapy in one institution, and derive recommendations for optimum starting and maintenance replacement therapy with hydrocortisone. DESIGN Retrospective survey of clinical management using a clinical information system and the patient case notes. PATIENTS Using the department’s clinical information system, 210 patients were identified who had been treated with hydrocortisone. Case notes were reviewed and 130 patients were identified whose records contained the results of at least one valid hydrocortisone day curve. Data on 174 day curves performed on these patients (65 on twice daily and 109 on thrice daily hydrocortisone regimes) formed the basis of this analysis. METHODS Hydrocortisone day curves had been performed as part of routine clinical management: patients collected a 24 h urine for free cortisol on the day prior to the test and took their morning hydrocortisone at the normal time, at home, on wakening. During a day-case attendance serum cortisol was then measured at 0900 h, 1230 h (prior to any lunchtime dose) and 1730 h (prior to the evening dose). ‘Optimal replacement’ was arbitrarily defined as that dose which achieved a UFC and 09:00h cortisol within the reference range for the normal population (to avoid over-replacement) combined with 1230 h and 1730 h cortisol above 50 nmol/l, and ideally above 100 nmol/l (to avoid under-replacement). Raw data from all hydrocortisone day curves was analysed in an Excel spreadsheet to determine the effect of different dose regimens on the percentage of patients achieving each and all of these 4 criteria, and on an overall ‘quality score’ (comprising 1 point for each of the 4 criteria attained). RESULTS Patients on twice daily hydrocortisone regimes achieved optimal replacement in 15% of cases compared to 60% on thrice daily regimes (P < 0.001 by χ²); mean overall ‘quality scores’ for these regimens were 2.72 and 3.49 respectively (P < 0.001 by t-test). Of individual dose regimens with sufficient cases for valid comparison, a dose of 10 mg/5 mg/5 mg (rising/lunch/evening) achieved optimal replacement in 66% and mean ‘quality score’ of 3.62 (n = 53), compared to 50% and 3.32 for 10 mg/10 mg/5 mg (n = 28) and 10% and 2.48 for 20 mg/–/10 mg (n =29). CONCLUSIONS The use of arbitrary, but logical, criteria to assess the quality of hydrocortisone replacement regimens indicates that optimal replacement is achieved with thrice daily hydrocortisone regimens, and that the traditional twice daily regime results in a 0900 h cortisol above normal in one-third, and late afternoon cortisol below 50 nmol/l in one-half of patients thus treated. An appropriate starting dose of hydrocortisone of 10 mg/5 mg/5 mg (rising/lunch/evening) is suggested, with subsequent individual adjustment based on simple hydrocortisone day curves.     

Optimizing glucocorticoid replacement therapy in severely adrenocorticotropin-deficient hypopituitary male patients

Background The optimal replacement regimen of hydrocortisone in adults with severe ACTH deficiency remains unknown. Management strategies vary from treatment with 15–30 mg or higher in daily divided doses, reflecting the paucity of prospective data on the adequacy of different glucocorticoid regimens. Objective Primarily to define the hydrocortisone regimen which results in a 24 h cortisol profile that most closely resembles that of healthy controls and secondarily to assess the impact on quality of life (QoL). Design Ten male hypopituitary patients with severe ACTH deficiency (basal cortisol <100 nm and peak response to stimulation <400 nm ) were enrolled in a prospective, randomized, crossover study of 3 hydrocortisone dose regimens. Following 6 weeks of each regimen patients underwent 24 h serum cortisol sampling and QoL assessment with the Short Form 36 (SF36) and the Nottingham Health Profile (NHP) questionnaires. Free cortisol was calculated using Coolen’s equation. All results were compared to those of healthy, matched controls. Results Corticosteroid binding globulin (CBG) was significantly lower across all dose regimens compared to controls (P < 0·05). The lower dose regimen C (10 mg mane/5 mg tarde) produced a 24 h free cortisol profile (FCP) which most closely resembled that of controls. Both regimen A(20 mg mane/10 mg tarde) and B(10 mg mane/10 mg tarde) produced supraphysiological post‐absorption peaks. There was no significant difference in QoL in patients between the three regimens, however energy level was significantly lower across all dose regimens compared to controls (P < 0·001). Conclusions The lower dose of hydrocortisone (10 mg/5 mg) produces a more physiological cortisol profile, without compromising QoL, compared to higher doses still used in clinical practice. This may have important implications in these patients, known to have excess cardiovascular mortality.     

Comparison of different regimens of glucocorticoid replacement therapy in patients with hypoadrenalism

Since the optimal glucocorticoid replacement needs to avoid over and under treatment, the adequacy of different daily cortisone acetate (CA) doses was assessed in 34 patients with primary and central hypoadrenalism. The conventional twice CA 37.5 mg/day dose was administered to all patients (A regimen: 25 mg at 07:00 h, 12.5 mg at 15:00 h), while in 2 subgroups of 12 patients the dose was shifted on 2 thrice daily regimens (B: 25 mg at 07:00, 6.25 mg at 12: 00, 6.25 mg at 17:00; C: 12.5 mg, 12.5 mg, 12.5 mg). In other 12 patients the conventional dose was reduced to a thrice 25 mg/day administration (D regimen: 12.5 mg, 6.25 mg, 6.25 mg). In all patients, urinary free cortisol (UFC) excretion and cortisol day curves were evaluated. During the CA 37.5 mg administration, nadir cortisol levels were significantly higher with the thrice daily regimens (143 +/- 31 on B and 151 +/- 34 nmol/l on C) than with the conventional twice (85 +/- 16 nmol/l). Moreover, UFC, morning cortisol levels and mean cortisol day curves were similar in each group. Finally, during D regimen nadir cortisol levels were higher than in A and similar to B and C regimens. No difference in UFC and in cortisol day curves by reducing the CA dose was found. In conclusion, the thrice daily cortisone regimens, in which more physiological cortisol levels are achieved, perform better as replacement therapy. The administration of 25 mg/day CA confirms that replacement therapy is more adequate with a lower dose, particularly in patients with central hypoadrenalism.     

Dose distribution in hydrocortisone replacement therapy has a significant influence on urine free cortisol excretion.

We investigated the influence of dose distribution in hydrocortisone replacement therapy on urine free cortisol excretion. To this end, we measured 24-hour urine free cortisol (24-h UFC) in 13 patients with hypocortisolism. The patients took 25 mg hydrocortisone/day according to the following schedules: either a single 25 mg hydrocortisone dose at 8:00 a.m., or 15 mg hydrocortisone at 8:00 a.m. and 10 mg hydrocortisone at 2:00 p.m., or 5 mg hydrocortisone at 8:00 a.m., 10:00 a.m., 2:00 p.m., 6:00 p.m. and 10:00 p.m. 24-h UFC decreased significantly with increasing division of the daily 25 mg hydrocortisone dose. When taking 25 mg hydrocortisone in a single morning dose, the mean 24-h UFC was 649 +/- 52 nmol/day (mean +/- SEM). When the daily dose was divided into doses of 15 mg and 10 mg hydrocortisone, 24-h UFC was reduced by 28 % to 466 +/- 39 nmol/day (p < 0.002). After division into five doses of 5 mg, 24-h UFC was reduced by 42.8 % to 371 +/- 36 nmol/day (p < 0.001) compared to the single 25 mg dose. These data demonstrate that consideration of the dose distribution in hydrocortisone replacement therapy when analysing 24-h UFC is of clinical importance.     

What is the best approach to tailoring hydrocortisone dose to meet patient needs in 2012?

Cortisol is an essential stress hormone and replacement with oral hydrocortisone is lifesaving in patients with adrenal insufficiency. Cortisol has a diurnal rhythm regulated by the central body clock and this rhythm is a metabolic signal for peripheral tissue clocks. Loss of cortisol rhythmicity is associated with fatigue, depression and insulin resistance. A general principle in endocrinology is to replace hormones to replicate physiological concentrations; however, the pharmacokinetics of oral immediate‐release hydrocortisone make it impossible to fully mimic the cortisol rhythm and patients still have an increased morbidity and mortality despite replacement. Traditionally, physicians have replaced hydrocortisone with a total daily dose based on the diurnal 24‐h cortisol production rate with hydrocortisone given twice or thrice daily, with the highest dose first thing in the morning. Monitoring treatment and dose titration has been much debated with some clinicians using cortisol day curves and others relying on clinical symptoms. The main challenge is that there is no established biomarker of cortisol activity. In addressing the clinical question, we have taken the view that an understanding of the cortisol circadian rhythm and hydrocortisone pharmacokinetics is essential when tailoring hydrocortisone dose. Using this approach, we have developed a thrice daily, weight‐related, dosing regimen and a pharmacokinetic and clinical method to monitor treatment. Our argument for replicating the cortisol circadian rhythm is based on the observation that disruption of the rhythm is associated with ill health, and the few studies that have compared different treatment regimens. Further studies are required to definitively test the benefits of replacing the cortisol circadian rhythm in patients with adrenal insufficiency.     

Doses and steroids to be used in primary and central hypoadrenalism

Traditionally hydrocortisone has been the first choice for replacement therapy in patients with adrenal insufficiency. Paediatricians have used body surface area adjusted dosing and adult physicians have tended to use fixed doses twice or thrice daily. Cortisol secretion has a distinct circadian rhythm being low at the time sleep onset, rising from between 02.00 h and 04.00 h in the morning to peak just after the time of waking then falling during the day. The pharmacokinetics of immediate release hydrocortisone means that no treatment regimen is capable of simulating the normal circadian rhythm of cortisol. Recent data with hydrocortisone infusions suggests that circadian delivery of hydrocortisone can improve biochemical control of patients with adrenal insufficiency. It is anticipated in the future that modified release formulations of hydrocortisone will provide more optimal replacement therapy.     

Syndrome of inappropriate secretion of antidiuretic hormone (SIADH) and adrenal insufficiency induced by rathke's cleft cyst: a case report

We report a case of a seventy-year-old woman with syndrome of inappropriate secretion of antidiuretic hormone (SIADH) and adrenal insufficiency induced by Rathke's cleft cyst. She experienced nausea, vomiting, diarrhea, and headache and disturbance of consciousness induced by hyponatremia at a serum sodium level of 100 mEq/l. In spite of severe hyponatremia, urinary sodium excretion was not suppressed and serum osmolality (270 mOsm/kg) was lower than urine osmolality (304 mOsm/kg), and arginine vasopressin (AVP) remained within normal range. SIADH was diagnosed because she was free from other diseases known to cause hyponatremia such as dehydration, cardiac dysfunction, liver dysfunction, renal dysfunction, hypothyroidism, and adrenal insufficiency. Cranial computed tomographic (CT) scan and cranial magnetic resonance (MR) imaging showed a cystic lesion of approximately 2 cm in diameter in the pituitary gland. These images suggested that the cystic lesion was a Rathke's cleft cyst, which was the cause of SIADH. Water restriction therapy normalized her serum sodium concentration and improved her symptoms. After one year, she suffered from general fatigue, appetite loss, fever, and body weight loss (5 kg/2 months). She had neither hypotension nor hypoglycemia, but her serum sodium level was low and serum cortisol, ACTH, and urine free cortisol were very low. Therefore, secondary adrenal insufficiency was suspected and diagnosed by stimulation tests. After start of hydrocortisone replacement therapy (10 mg/day), her symptoms disappeared. In conclusion, Rathke's cleft cyst should be kept in mind as a potential cause in a patient with SIADH, hypopituitarism, and/or adrenal insufficiency.     

Short term effects of ketoconazole in Cushing's syndrome

The effects of Ketoconazole (600 mg/day) were evaluated in 10 patients with Cushing's syndrome during a mean period of 4.5 weeks (range 1-12). The urinary free cortisol excretion (UFC) decreased by 21 +/- 15% (mean +/- SEM) (p less than 0.01) on day 1; 54 +/- 8% (p less than 0.0001) on day 2; 60 +/- 15% (p less than 0.0001) on day 3 and 87 +/- 3% (p less than 0.0001) on day 8 compared to baseline. Salivary cortisol at 0800 h decreased similarly. On day 3, 7 patients showed normal UFC values and on day 8, only 1 patient, with the ectopic ACTH syndrome, had persistent hypercortisolism. The cortisol decrease was associated with an increase in desoxycorticosterone values (p less than 0.01) and a decrease in dehydroepiandrosterone sulfate (p less than 0.001), delta 4 androstenedione (p less than 0.05) and testosterone (p less than 0.05). No significant variations were observed in ACTH, 11 desoxycortisol, aldosterone, plasma renin activity, corticosteroid-binding globulin and sex hormone-binding globulin. Side effects were few: mild clinical adrenal insufficiency (n = 5), oedema (n = 3) and reversible hepatic toxicity (n = 1). We conclude that Ketoconazole is an effective inhibitor of cortisol and androgens synthesis. It is well tolerated, rapidly effective and its efficacy persists unchanged for at least one month in all forms of Cushing's syndromes. For these reasons Ketoconazole may be a valuable drug for preoperative treatment of Cushing's syndrome.     

Effect of rifampin on the metabolism of glucocorticoids in Addison's disease

To investigate the effect of rifampicin on the metabolism of hydrocortisone, we measured serum sodium level and blood glucose concentration before lunch in a patient with Addison's disease when treated with hydrocortisone 30 mg/day alone and together with rifampicin 450 mg/day for more than two weeks. We also studied the area under the plasma cortisol curve (AUC), half-life (T 1/2) and clearance rate (CLs) of hydrocortisone after both oral ingestion and intravenous injection of 20 mg hydrocortisone. The results showed that rifampicin increased the metabolism of cortisol by shortening of its T 1/2, increasing its CLs and decreasing its AUC. It decreases the blood sodium level and glucose concentration and makes the patient liable to have hypoglycemic symptoms before lunch. We conclude that the increase of metabolism of cortisol after simultaneous taking of rifampicin may induce adrenal crisis in Addison's disease.     

Adrenal gland volume and dexamethasone-suppressed cortisol correlate with total daily salivary cortisol in African-American women

CONTEXT: Population-based studies of associations between subclinical hypercortisolism and risk for disease states, such as type 2 diabetes mellitus, have been difficult to assess because of imprecise measures of glucocorticoid exposure. Alternative measures (salivary cortisol and adrenal gland volume) have not been systematically compared with 24-h urine free cortisol (UFC) in a healthy population. OBJECTIVE: Our objectives were: 1) to determine whether 24-h UFC and total daily salivary cortisol correlated with each other, adrenal gland volume, and salivary cortisol after dexamethasone suppression and 2) to evaluate the association of adrenal gland volume with salivary cortisol after dexamethasone suppression. DESIGN, SETTING, AND PARTICIPANTS: This was a cross-sectional study of 20 healthy, premenopausal African-American women aged 18-45 yr. MAIN OUTCOME MEASURES: Salivary cortisol was assessed at six time points throughout the day simultaneous with 24-h UFC collection. Adrenal gland volume was measured by computed tomography scan. Dexamethasone-suppressed salivary cortisol was measured at 0800 h after administration of 0.5 mg dexamethasone at 2300 h the prior evening. RESULTS: Dexamethasone-suppressed salivary cortisol levels correlated strongly with individual, timed salivary cortisol measurements, total daily salivary cortisol (rs=0.75; P=0.0001; n=20), and adrenal gland volume (rs=0.66; P=0.004; n=17). Total daily salivary cortisol and adrenal gland volume also correlated (rs=0.46; P=0.04; n=19). In contrast, 24-h UFC levels did not correlate with any of the other hypothalamic-pituitary-adrenal axis measures. CONCLUSION: A dexamethasone suppression test or adrenal gland volume may be alternative measures for characterizing subtle subclinical hypercortisolism in healthy adults.     

Flutamide decreases cortisol clearance in patients with congenital adrenal hyperplasia

Classic congenital adrenal hyperplasia due to 21-hydroxylase deficiency is characterized by a defect in cortisol and aldosterone secretion and adrenal hyperandrogenism. Current treatment is to provide adequate glucocorticoid and mineralocorticoid substitution to prevent adrenal crises and to suppress excess adrenal androgen secretion. Satisfactory adrenocortical suppression often requires supraphysiological doses of hydrocortisone, which may produce an unacceptable degree of hypercortisolism. A new four-drug treatment regimen of flutamide, testolactone, reduced hydrocortisone dose, and 9alpha-fludrocortisone has been shown to achieve normal growth and development after 2 yr of therapy and may, therefore, represent a potential alternative approach to the treatment of children with classic congenital adrenal hyperplasia. We investigated the effect of flutamide and testolactone, and flutamide alone, on cortisol clearance by performing clearance studies twice in 13 children (6 males and 7 females; age range, 7.0-14.5 yr) with classic 21-hydroxylase deficiency. All studies were conducted at least 3 months after institution of the four-drug treatment regimen. In eight patients (group 1), the first cortisol clearance study was performed on the four-drug regimen, and the second study was performed after a 48-h washout period off flutamide and testolactone. In five patients (group 2), the first study was conducted 1 wk after discontinuation of testolactone and while patients were receiving flutamide, hydrocortisone and 9alpha-fludrocortisone, and the second study was performed after a 48-h washout period off flutamide. Oral hydrocortisone was held on the day of the clearance studies, and all patients received a continuous infusion of hydrocortisone (0.6 mg/m(2).h) from 1800 h to 0200 h, with cortisol concentrations measured once hourly. In addition, an in vitro study was conducted to exclude the possibility of an analytical interference of flutamide, 2-hydroxyflutamide, and testolactone with the serum cortisol immunoassay. Total body cortisol clearance was significantly lower during treatment with the four-drug regimen than during treatment with hydrocortisone and 9alpha-fludrocortisone (153.5 +/- 26.8 vs.355.4 +/- 65.8 ml/min; P = 0.001). Similar results were obtained comparing flutamide, hydrocortisone, and 9alpha-fludrocortisone therapy to hydrocortisone and 9alpha-fludrocortisone therapy (155.8 +/- 26.5 vs. 281.8 +/- 96.2 ml/min; P = 0.037). The in vitro study indicated that an interference with the serum cortisol immunoassay was unlikely. These findings indicate that the addition of flutamide and testolactone to the treatment regimen of hydrocortisone and 9alpha-fludrocortisone decreases cortisol clearance in patients with classic 21-hydroxylase deficiency, and this effect seems to be due to flutamide. Glucocorticoid replacement doses should be reduced when flutamide is added to the treatment regimen of patients receiving hydrocortisone.     

A case of adrenal tuberculosis complicated with acute exacerbation of adrenal insufficiency during the initial phase of anti-tuberculosis therapy for pulmonary tuberculosis

A 36-year-old male was admitted to our hospital because of adrenal insufficiency. About one month before admission, he was diagnosed as pulmonary tuberculosis and started anti-tuberculosis therapy with isoniazid, rifampicin, ethambutol, and pyrazinamide. On the tenth day, general fatigue, abdominal pain, nausea and diarrhea developed, and laboratory examination showed hyponatremia [126 mEq/l]. Enhanced CT on admission revealed bilateral adrenal mass-like enlargement, and further examination showed high level of plasma ACTH, and low level of cortisol. These findings led to a diagnosis of adrenal insufficiency caused by adrenal tuberculosis. He was treated with hydrocortisone and his signs and symptoms rapidly improved. We suppose adrenal insufficiency became clinically apparent because rifampicin reduced half-life of serum cortisol. Interestingly we observed rapid increase and decrease in size of bilateral adrenal glands on CT scan during the course.     

Glucocorticoid replacement therapy and fibrinolysis in patients with hypopituitarism

Background Hypopituitarism is associated with increased cardiovascular mortality, and it has been suggested that unphysiological glucocorticoid replacement regimens might contribute to this risk. Traditional glucocorticoid replacement regimens have often led to excessive serum cortisol levels. The hypercortisolaemia of Cushing’s syndrome is associated with an increased risk of thromboembolism. Objective To examine whether short‐term higher‐dose hydrocortisone replacement regimens adversely affect the fibrinolytic system. Design Crossover study comparing tailored low‐dose (LD) glucocorticoid regimen (mean, 17·5 mg hydrocortisone daily), with a traditional high‐dose (HD, 30‐mg hydrocortisone daily) regimen for 2 weeks. Patients Ten patients with hypopituitarism and ACTH deficiency – median (range) age, 59 (41–75) years – and 10 age‐ and sex‐matched controls. Nine patients had growth hormone deficiency (five replaced), nine patients had TSH deficiency (nine replaced), eight had gonadotrophin deficiency (five replaced). During the study, other pituitary hormone replacement therapy remained unchanged. Patients with acromegaly and Cushing’s syndrome were excluded. Measurements Hourly serum cortisol for 11 h, plasminogen activator inhibitor‐1 (PAI‐1), tissue plasminogen activator (tPA) and fibrinogen levels after 2 weeks of treatment with both LD and HD regimens. Results No overall significant differences were found between the three groups using the Kruskal–Wallis test: PAI‐1: [median (range)] HD, 25 (5–53) ng/ml; LD, 21 (4–56) ng/ml; controls, 27 (8–51); P = 0·3; tPA: HD, 10 (5–15) ng/ml; LD, 10 (4–13) ng/ml; controls 10 (3–13); P = 0·46; and fibrinogen: HD, 2·5 (1·8–3·5) g/l; LD, 3·0 (2·3–4·4) g/l; controls, 2·6 (1·6–3·2): P = 0·97 In addition, no significant differences between HD and LD using Wilcoxon’s paired test; PAI‐1 (P = 0·91), tPAag (P = 0·47) and fibrinogen (P = 0·09). Conclusions An increased dose of hydrocortisone for 2 weeks creates excessive glucocorticoid exposure, but does not significantly affect fibrinolytic‐coagulation parameters.     

Clinical characteristics, timing of peak responses and safety aspects of two dosing regimens of the glucagon stimulation test in evaluating growth hormone and cortisol secretion in adults

Weight-based (WB: 0.03 mg/kg) and fixed dose (FD: 1–1.5 mg) regimens of the glucagon stimulation test (GST) have been used to evaluate GH and cortisol secretion in children and adults, respectively. However, experience of the WB regimen in assessing GH and cortisol secretion in adults are limited. We describe a multicenter experience using WB and FD regimens in evaluating GH and cortisol secretion in adults suspected of GH deficiency and central adrenal insufficiency. Retrospective case series of GSTs (n = 515) performed at five tertiary centers. Peak and nadir glucose, and peak GH and peak cortisol responses occurred later with WB (mean dose: 2.77 mg) compared to FD (mean dose: 1.20 mg) regimens. Main side-effects were nausea and vomiting, particularly in younger females. Nausea was comparable but vomiting was more frequent in the WB regimen (WB: 10.0 % vs FD: 2.4 %; P < 0.05). Peak and nadir glucose, ΔGH, and peak and Δcortisol were higher in the WB regimen. In both regimens, age correlated negatively with peak cortisol levels, and body mass index (BMI), fasting, peak and nadir glucose correlated negatively with peak GH levels. WB and FD regimens can induce adult GH and cortisol secretion, but peak responses occur later in the WB regimen. Both regimens are relatively safe, and vomiting was more prevalent in the WB regimen. As age, BMI, and glucose tolerance negatively correlated with peak GH and cortisol levels, the WB regimen may be more effective than the FD regimen in older overweight glucose intolerant patients.     

Weight-related dosing, timing and monitoring hydrocortisone replacement therapy in patients with adrenal insufficiency

OBJECTIVE: The objective of this study was to examine the variables determining hydrocortisone (HC) disposition in patients with adrenal insufficiency and to develop practical protocols for individualized prescribing and monitoring of HC treatment. DESIGN AND PATIENTS: Serum cortisol profiles were measured in 20 cortisol-insufficient patients (09.00 h cortisol < 50 nmol/l) given oral HC as either a fixed or 'body surface area-adjusted' dose in the fasted or fed state. Endogenous cortisol levels were measured in healthy subjects. Pharmacokinetic analysis was performed using P-Pharm software, and computer simulations were used to assess the likely population distribution of the data. RESULTS: Body weight was the most important predictor of HC clearance. A fixed 10-mg HC dose overexposed patients to cortisol by 6.3%, whereas weight-adjusted dosing decreased interpatient variability in maximum cortisol concentration from 31 to 7%, decreased area under the curve (AUC) from 50 to 22% (P < 0.05), and reduced overexposure to < 5%. Food taken before HC delayed its absorption. Serum cortisol measured 4 h after HC predicted cortisol AUC (r(2) = 0.78; P < 0.001). CONCLUSIONS: We recommend weight-adjusted HC dosing, thrice daily before food, monitored with a single serum cortisol measurement using a nomogram. This regimen was prospectively examined in 40 cortisol-insufficient patients, 85% of whom opted to remain on the new thrice-daily treatment regimen.     

A case of cushing syndrome with both secondary hypothyroidism and hypercalcemia due to postoperative adrenal insufficiency

A 48-year-old woman was referred to our hospital because of secondary hypothyroidism. Upon admission a left adrenal tumor was also detected using computed tomography. Laboratory data and adrenal scintigraphy were compatible with Cushing syndrome due to the left adrenocortical adenoma, although she showed no response to the TRH stimulation test. Hypercortisolism resulting in secondary hypothyroidism was diagnosed. After a left adrenalectomy, hydrocortisone administration was begun and the dose was reduced gradually. After discharge on the 23rd postoperative day, she began to suffer from anorexia. ACTH level remained low, and serum cortisol, free thyroxine and TSH levels were within the normal range. Since her condition became worse, she was re-admitted on the 107th postoperative day at which time serum calcium level was high (15.6 mg/dl). Both ACTH response to the CRH stimulation test and TSH response to the TRH stimulation test were restored to almost normal levels, but there was no response of cortisol to CRH stimulation test. We diagnosed that the hypercalcemia was due to adrenal insufficiency. Although the serum calcium level decreased to normal after hydrocortisone was increased (35 mg/day), secondary hypothyroidism recurred. It was suggested that sufficient glucocorticoids suppressed TSH secretion mainly at the pituitary level, which resulted in secondary (corticogenic) hypothyroidism. However, both postoperative glucocorticoid deficiency and adequate amounts of thyroxine due to the elimination of inhibition of TSH secretion by glucocorticoids might cause hypercalcemia possibly through increased bone reabsorption of calcium.     

Variability in hydrocortisone plasma and saliva pharmacokinetics following intravenous and oral administration to patients with adrenal insufficiency

OBJECTIVE: The best method for determining hydrocortisone replacement therapy is not well defined. This study aimed to assess interindividual variability in cortisol pharmacokinetics and to investigate whether measurement of salivary cortisol provides a useful alternative to plasma concentration measurements. DESIGN: Intravenous (IV) and oral crossover. PATIENTS: Twenty-seven patients with primary or secondary adrenal insufficiency who had been on stable replacement therapy for at least 3 months. MEASUREMENTS: Plasma and salivary concentrations of cortisol were measured up to 8 h following administration of hydrocortisone. RESULTS: After IV administration, Cmax ranged from 715 to 8313 nmol/l, area under the curve (AUC) from 1112 to 12 177 nmol h/l and cortisol clearance had a median (range) of 0.267 (0.076-0.540) l/h/kg. After oral administration, Cmax ranged from 422 to 1554 nmol/l, AUC 1081-5471 nmol h/l and oral clearance had a median (range) of 0.267 (0.081-0.363) l/h/kg. There was no clear relationship between paired saliva and plasma cortisol concentrations after IV or oral dosing. Plasma and salivary AUC(2-8 h) after IV administration were highly correlated (r2 = 0.77) but differences between predicted and measured plasma AUCs ranged from 3% to 90%. There was a poor correlation between plasma and saliva AUC(2-6 h) after oral administration (r2 = 0.16). CONCLUSIONS: The wide interindividual variability in plasma and salivary profiles of cortisol following the administration of IV and oral hydrocortisone to patients with adrenal insufficiency and the poor correlation between salivary and plasma measurements suggest that salivary cortisol measurements cannot be used for individual hydrocortisone dosage adjustment.     

Bioavailability of oral hydrocortisone in patients with congenital adrenal hyperplasia due to 21-hydroxylase deficiency

The management of congenital adrenal hyperplasia due to 21-hydroxylase (CYP21) deficiency requires glucocorticoid substitution with oral hydrocortisone given twice or thrice daily. In paediatric practice little is known of the bioavailability of oral hydrocortisone tablets used in these patients. The aim of this study was to assess the bioavailability of oral hydrocortisone and to evaluate current replacement therapy in the light of cortisol pharmacokinetic properties. We determined the bioavailability of hydrocortisone following oral and intravenous administration in sixteen (median age: 10.9 years, range: 6.0-18.4 years) adequately controlled CYP21 deficient patients. Serum total cortisol concentrations were measured at 20-min intervals for 24 h while patients were on oral substitution therapy, and at 10-min intervals for 6 h following an intravenous bolus of hydrocortisone in a dose of 15 mg/m(2) body surface area. The area under the serum total cortisol concentration versus time curve (AUC) following oral and intravenous administration of hydrocortisone was calculated using the trapezoid method. The bioavailability was estimated by dividing the corrected for dose AUC after oral hydrocortisone administration by the corrected for dose AUC after the intravenous hydrocortisone administration and was exemplified as a percentage. After oral administration of hydrocortisone in the morning, median serum total cortisol concentrations reached a peak of 729.5 nmol/l (range: 492-2520 nmol/l) at 1.2 h (range: 0.3-3.3 h) and declined monoexponentially thereafter to reach undetectable concentrations 7 h (range: 5-12 h) after administration. Following administration of the evening hydrocortisone dose, median peak cortisol concentration of 499 nmol/l (range: 333-736 nmol/l) was attained also at 1.2 h (range: 0.3-3.0 h) and subsequently declined gradually, reaching undetectable concentrations at 9 h (5-12 h) after administration of the oral dose. After the intravenous hydrocortisone bolus a median peak serum total cortisol concentration of 1930 nmol/l (range: 1124-2700 nmol/l) was observed at 10 min (range: 10-20 min). Serum cortisol concentrations fell rapidly and reached undetectable levels 6 h after the hydrocortisone bolus. The absolute bioavailability of oral hydrocortisone in the morning was 94.2% (90% confidence interval (CI): 82.8-105.5%) whereas the apparent bioavailability in the evening was estimated to be 128.0% (90% CI: 119.0-138.0%). We conclude that the bioavailability of oral hydrocortisone is high and may result in supraphysiological cortisol concentrations within 1-2 h after administration of high doses. The even higher bioavailability in the evening, estimated using as reference the data derived from the intravenous administration of hydrocortisone bolus in the morning, is likely to reflect a decrease in the hydrocortisone clearance in the evening. Decisions on the schedule and frequency of administration in patients with congenital adrenal hyperplasia should be based on the knowledge of the bioavailability and other pharmacokinetic parameters of the hydrocortisone formulations currently available.     

Isolated corticotrophin deficiency

Isolated ACTH deficiency (IAD) is a rare disorder, characterized by secondary adrenal insufficiency (AI) with low or absent cortisol production, normal secretion of pituitary hormones other than ACTH and the absence of structural pituitary defects. In adults, IAD may appear after a traumatic injury or a lymphocytic hypophysitis, the latter possibly due to autoimmune etiology. Conversely, a genetic origin may come into play in neonatal or childhood IAD. Patients with IAD usually fare relatively well during unstressed periods until intervening events spark off an acute adrenal crisis presenting with non specific symptoms, such as asthenia, anorexia, unintentional weight loss and tendency towards hypoglycemia. Blood chemistry may reveal mild hypoglycemia, hyponatremia and normal-high potassium levels, mild anemia, lymphocytosis and eosinophilia. Morning serum cortisol below 3 μg/dl are virtually diagnostic for adrenal insufficiency. whereas cortisol values comprised between 5–18 μg/dl require additional investigations: insulin tolerance test (ITT) is considered the gold standard but—when contraindicated—high or low dose-ACTH stimulation test with serum cortisol determination provides a viable alternative. Plasma ACTH concentration and prolonged ACTH infusion test are useful in differential diagnosis between primary and secondary adrenal insufficiency. For some patients with mild, near-to-asymptomatic disease, glucocorticoid replacement therapy may not be required except during stressful events; for symptomatic patients, replacement doses i.e., mean daily dose 20 mg (0.30 mg/kg) hydrocortisone or 25 mg (0.35 mg/kg) cortisone acetate, are usually sufficient. Administration of mineralocorticoids is generally not necessary as their production is maintained.     

SFE/SFEDP adrenal insufficiency French consensus: Introduction and handbook

The French endocrinology society (SFE) and the French pediatric endocrinology society (DFSDP) have drawn up recommendations for the management of primary and secondary adrenal insufficiency in the adult and child, based on an analysis of the literature by 19 experts in 6 work-groups. A diagnosis of adrenal insufficiency should be suspected in the presence of a number of non-specific symptoms except hyperpigmentation which is observed in primary adrenal insufficiency. Diagnosis rely on plasma cortisol and ACTH measurement at 8am and/or the cortisol increase after synacthen administration. When there is a persistant doubt of secondary adrenal insufficiency, insulin hypoglycemia test should be carried out in adults, adolescents and children older than 2 years. For determining the cause of primary adrenal insufficiency, measurement of anti-21-hydroxylase antibodies is the initial testing. An adrenal CT scan should be performed if auto-antibody tests are negative, then assay for very long chain fatty acids is recommended in young males. In children, a genetic anomaly is generally found, most often congenital adrenal hyperplasia. In the case of isolated corticotropin (ACTH) insufficiency, it is recommended to first eliminate corticosteroid-induced adrenal insufficiency, then perform an hypothalamic-pituitary MRI. Acute adrenal insufficiency is a serious condition, a gastrointestinal infection being the most frequently reported initiating factor. After blood sampling for cortisol and ACTH assay, treatment should be commenced by parenteral hydrocortisone hemisuccinate together with the correction of hypoglycemia and hypovolemia. Prevention of acute adrenal crisis requires an education of the patient and/or parent in the case of pediatric patients and the development of educational programs. Treatment of adrenal insufficiency is based on the use of hydrocortisone given at the lowest possible dose, administered several times per day. Mineralocorticoid replacement is often necessary for primary adrenal insufficiency but not for corticotroph deficiency. Androgen replacement by DHEA may be offered in certain conditions. Monitoring is based on the detection of signs of under- and over-dosage and on the diagnosis of associated auto-immune disorders.